In the Quantum picture of the world, each individual event cannot be determined exactly, but has to be described by a wave of probability. There is a kind of polarity between the position and energy of any particle in which they cannot be simultaneously determined. This was not a failing of experimental method but a property of the kinds of mathematical structures that physicists have to use to describe this realm of the world. The famous equation of Quantum theory embodying Heisenberg's Uncertainty Principle is: Planck's constant = (uncertainty in energy) x (uncertainty in position)
Thus if we try to fix the position of the particle (i.e., reduce the uncertainty in its position to a small factor) then as a consequence of this equation the uncertainty in the energy must increase to balance this, and therefore we cannot find a value for the energy of the particle simultaneous with fixing its position. Planck's constant being very small means that these infractions as based of the factors only become dominant on the extremely small scale, which are within the realm of the atom.
So we see that the Quantum picture of reality has at its foundation a non-deterministic view of the fundamental building Forms of matter. Of course, when dealing with large masses of particles these quantum indeterminacies effectively cancel each other out, and physicists can determine and predict the state of large systems. Obviously planets, suns, galaxies being composed of large numbers of particles do not exhibit any uncertainty in their position and energies, for when we look at such large aggregates as some of its totality, the total quantum uncertainty is a systems reduction as placed by zero, and in respect to their large scale properties can effectively be treated as deterministic systems.
Thus on the large scale we can effectively apply a deterministic physics, but when we wish to look in detail at the properties of the sub-atomic realm, lying at the root and foundation of our world, we must enter a domain of quantum uncertainties and find the neat ordered picture dissolving into a sea of ever flowing forces that we cannot tie down or set into fixed patterns.
Some people when faced with this picture of reality find comfort in dismissing the quantum world as having little to do with the "real world" of appearances. We do not live within the sub-atomic level after all. However, it does spill out into our outer world. Most of the various electronic devices of the past decades rely on the quantum tunnelling effect in transistors and silicon chips. The revolution in quantum physics has begun to influence the life sciences, and biologists and botanists are beginning to come up against quantum events as the basis of living systems, in the structure of complex molecules in the living tissues and membranes of cells for example. When we look at the blue of the sky, we are looking at a phenomenon only recently understood through quantum theory.
Although the Quantum picture of reality might seem strange indeed, I believe the picture it presents of the foundations of the material world, the ever flowing sea of forces metamorphosing and interacting through the medium of "virtual" or quantum messenger particles, has certain parallels with nature of our consciousness.
I believe that if we try to examine the nature of our consciousness we will find at its basis it exhibits "quantum" like qualities. Seen from a distant, large scale and external perspective, we seem to be able to structure our consciousness in an exact and precise way, articulating thoughts and linking them together into long chains of arguments and intricate structures. Our consciousness can build complex images through its activity and seems to have all the qualities of predictability and solidity. The consciousness of a talented architect is capable of designing and holding within itself an image of large solid structures such as great cathedrals or public buildings. A mathematician is capable of inwardly picturing an abstract mathematical system, deriving its properties from a set of axioms.
In this sense our consciousness might appear as an ordered and deterministic structure, capable of behaving like and being explicable in the same terms as other large scale structures in the world. However, this is not so. For if we through introspection try to examine the way in which we are conscious, in a sense to look at the atoms of our consciousness, this regular structure disappears. Our consciousness does not actually work in such an ordered way. We only nurture an illusion if we try to hold to the view that our consciousness is fixed by an ordered deterministic structure. True, we can create the large scale designs of the architect, the abstract mathematical systems, a cello concerto, but anyone who has built such structures within their consciousness knows that this is not achieved by a linear deterministic route.
Our consciousness is at its root a maverick, ever moving, increasing by its accommodating perception, feeling, thought, to another. We can never hold it still or focus it at a point for long. Like the quantum nature of matter, the more we try to hold our consciousness to a fixed point, the greater the uncertainty in its energy will become. So when we focus and narrow our consciousness to a fixed centre, it is all the more likely to jump with a great rush of energy to some seemingly unrelated aspect of our inner life suddenly. We all have such experiences each moment of the day. As in our daily work we try to focus our mind upon some problem only to experience a shift to another domain in ourselves suddenly, another image or emotional current intrudes then vanishes again, like an ephemeral virtual particle in quantum theory.
Those who begin to work upon their consciousness through some kinds of meditative exercises will experience these quantum uncertainties in the field of consciousness in a strong way.
In treating our consciousness as if it were a digital computer or deterministic machine after the model of 19th century science, I believe we foster a limited and false view of our inner world. We must now take the step toward a quantum view of consciousness, recognising that at its base and root our consciousness behaves like the ever flowing sea of the sub-atomic world. The ancient hermeticists foresaw consciousness as the "Inner Mercury.” Those who have experienced the paradoxical way in which the metal Mercury is both dense and metallic and yet so elusive, flowing and breaking up into small globules, and just as easily coming together again, will see how perceptive the alchemists were of the inner nature of consciousness, in choosing this analogy. Educators who treat the consciousness of children as if it were a filing cabinet to be filled with ordered arrays of knowledge are hopelessly wrong.
We can believe of the stepping stones whereby the formidable combinations await to the presence of the future, yet the nature of consciousness, and the look upon of what we see is justly to how this overlays links’ us with the mind/brain problem. The great difficulty in developing a theory of the way in which consciousness/mind is embodied in the activity of the brain, has I believe arisen out of the erroneous attempt to press a deterministic view onto our brain activity. Skinner and the behaviourist psychologists attempted to picture the activity of the brain as a computer where each cell behaved as an input/output device or a complex flip/flop. They saw nerve cells with their axons (output fibres) and dendrites (input fibres) being linked together into complex networks. An electrical impulse travelling onto a dendrite made a cell ‘fire’ and sent an impulse out along its axon so setting another nerve cell into action. The resulting patterns of nerve impulses constituted a reflex action, an impulse to move a muscle, a thought, a feeling, an intuitive experience. All could be reduced to the behaviour of this web of axons and dendrites of the nerve cells.
This simplistic picture, of course, was insufficient to explain even the behaviour of creatures like worms with primitive nervous systems, and in recent years this approach has largely been abandoned as it is becoming recognised that these events on the membranes of nerve cells are often triggered by shifts in the energy levels of sub-atomic particles such as electrons. In fact, at the root of such interactions lie quantum events, and the activity of the brain must now be seen as reflecting these quantum events.
The brain can no longer be seen as a vast piece of organic clockwork, but as a subtle device amplifying quantum events. If we trace a nerve impulse down to its root, there lies a quantum uncertainty, a sea of probability. So just how is it that this sea of probability can cast up such ordered structures and systems as the conception of a cello concerto or abstract mathematical entities? Perhaps here we may glimpse a way in which "spirit" can return into our physics.
The inner sea of quantum effects in our brain is in some way coupled to our ever flowing consciousness. When our consciousness focusses to a point, and we concentrate on some abstract problem or outer phenomenon, the physical events in our brain, the pattern of impulses, shifts in some ordered way. In a sense, the probability waves of a number of quantum systems in different parts of the brain, are brought into resonance, and our consciousness is able momentarily to create an ordered pattern that manifests physically through the brain. The thought, feeling, perception is momentarily earthed in physical reality, brought from the realm of the spiritual potential into outer actuality. This focussed ordering of the probability waves of many quantum systems requires an enormous amount of energy, but this can be borrowed in the quantum sense for a short instant of time. Thus we have through this quantum borrowing a virtual quantum state that is the physical embodiment of a thought, feeling, etc. However, as this can only be held for a short time, the quantum debt must be paid and the point of our consciousness is forced to jump to another quantum state, perhaps in another region of the brain. Thus our thoughts are jumbled up with emotions, perceptions, fantasy images.
The central point within our consciousness, our "spirit" in the hermetic sense, can now be seen as an entity that can work to control quantum probabilities. To our "spirits" our brain is a quantum sea providing a rich realm in which it can incarnate and manifest patterns down into the electrical/chemical impulses of the nervous system. (It has been calculated that the number of interconnections existing in our brains far exceeds the number of atoms in the whole universe - so in this sense the microcosm truly mirrors the macrocosm!). Our "spirit" allows the unswerving quantum, of which it borrows momentarily to press of a certain order into this sea that manifests the containment of a thought, emotion, etc. Such an ordered state can only exist momentarily, before our spirit or point of consciousness is forced to jump and move to other regions of the brain, where at that moment the pattern of probability waves for the particles in these nerve cells, can reflect the form that our spirit is trying with which to work.
This quantum borrowing to create regular patterns of probability waves is bought for a high price in that a degree of disorder must inevitably arise whenever the spirit tries to focus and reflect a linked sequential chain of patterns into the brain (such as we would experience as a logical adaption of our thought or some inward picture of some elaborate structure). Thus, it is not surprising that our consciousness sometimes brings to adrift and jumps about in a seemingly chaotic way. The quantum borrowing might also be behind our need for sleep and dream, allowing the physical brain to rid itself of the shadowy echos of these patterns pressed into it during waking consciousness. Dreaming may be that point in a cycle where consciousness and its vehicle interpenetrate and flow together, allowing the patterns and waves of probability to appear without any attempt to focus them to a point. In dream and sleep we experience our point of consciousness dissolving, decoupling and defocussing.
The central point of our consciousness, when actively thinking or feeling, must jump around the sea of patterns in our brain. (It is well known through neurophysiology that function cannot be located at a certain point in the brain, but that different areas and groups of nerve cells can take on a variety of different functions.) We all experience this when in meditation we merely let our consciousness move as it will. Then we come to sense the elusive mercurial eternal movement of the point of our consciousness within our inner space. You will find it to be a powerful and convincing experience if you try in meditation to follow the point of your consciousness moving within the space of your skull. Many religious traditions teach methods for experiencing this inner point of spirit.
I believe the movement of this point of consciousness, which appears as a pattern of probability waves in the quantum sea, must occur in extremely short segments of time, of necessity shorter than the time an electron takes to move from one state to another within the molecular structure of the nerve cell membranes. We are thus dealing in time scales significantly less than 10 to the power -16 of a second and possibly down to 10 to the power -43 of a second. During such short periods of time, the Heisenberg Uncertainty Principle that lies at the basis of quantum theory, means that this central spark of consciousness can borrow a large amount of energy, which explains how it can bring a large degree of ordering into a pattern. Although our point of consciousness lives at this enormously fast speed, our brain, which transforms this into a pattern of electro/chemical activity runs at a much slower rate. Between creating each pattern our spark of consciousness must wait almost an eternity for this to be manifested on the physical level. Perhaps this may account for the sense we all have sometimes of taking an enormous leap in consciousness, or travelling though vast realms of ideas, or flashes of images, in what is only a fleeting moment.
At around 10 to the power -43 of a second, time itself becomes quantized, that is it appears as discontinuous particles of time, for there is no way in which time can manifest in quantities less than 10 to the power -43 (the so-called Planck time). For here the borrowed quantum energies distort the fabric of space turning it back upon themselves. Their time must have a stop. At such short intervals the energies available are enormous enough to create virtual black holes and wormhole in space-time, and at this level we have only a sea of quantum probabilities - the so-called Quantum Foam. Contemporary physics suggests that through these virtual wormhole in space-time there are links with all time past and future, and through the virtual black holes even with parallel universes.
It must be somewhat above this level that our consciousness works, weaving probability waves into patterns and incarnating them in the receptive structure of our brains. Our being or spirit lives in this Quantum Foam, which is thus the Eternal Now, infinite in extent and a plenum of all possibilities. The patterns of everything that has been, that is now, and will come to be, exists latently in this quantum foam. Perhaps this is the realm though which the mystics stepped into timelessness, the eternal present, and sensed the omnipotence and omniscience of the spirit.
I believe that these exciting discoveries of modern physics could be the basis for a new view of consciousness and the way it is coupled to our physical nature in the brain. (Indeed, one of the fascinating aspects of Quantum theory which puzzles’ and mystifies contemporary physicists is the way in which their quantum description of matter requires that they recognise the consciousness of the observer as a factor in certain experiments. This enigma has caused not a few physicists to take an interest in spirituality especially inclining them to eastern traditions like Taoism or Buddhism, and in time I hope that perhaps even the hermetic traditions might prove worthy of their interest).
An important experiment carried out as recently as summer 1982 by the French physicist, Aspect, has unequivocally demonstrated the fact that physicists cannot get round the Uncertainty Principle and simultaneously determine the quantum states of particles, and confirmed that physicists cannot divorce the consciousness of the observer from the events observed. This experiment (in disproving the separability of quantum measurements) has confirmed what Einstein, Bohr and Heisenberg were only able to debate over philosophically - that with quantum theory we have to leave behind our naive picture of reality under which there happens as some unvaryingly compound structure if only to support its pictured clockwork. We are challenged by quantum theory to build new ways in which to picture reality, a physics, moreover, in which consciousness plays a central role, in which the observer is inextricably interwoven in the fabric of reality.
In a sense it may now be possible to build a new model of quantum consciousness, compatible with contemporary physics and which allows a space for the inclusion of the hermetic idea of the spirit. It may be that science has taken a long roundabout route through the reductionist determinism of the 19th century and returned to a more hermetic conception of our inner world.
In this short essay, incompletely argued though it may be, I hope I have at least presented some of the challenging ideas that lie behind the seeming negativity of our present age. For behind the hopelessness and despair of our times we stand on the brink of a great breakthrough to a new recognition of the vast spiritual depths that live within us all as human beings.
The idea that people may create devices that are conscious is known as artificial consciousness (AC). This is an ancient idea, perhaps dating back to the ancient Greek Promethean myth in which conscious people were supposedly manufactured from clay, pottery being an advanced technology in those days. In modern science fiction artificial people or conscious beings are described for being manufactured from electronic components. The idea of artificial consciousness (which is also known as machine consciousness (MC) or synthetic consciousness) is an interesting philosophical problem in the twenty first century because, with increased understanding of genetics, neuroscience and information processing it may soon be possible to create an entity that is conscious. It may be possible biologically to create a being by manufacturing a genome that had the genes necessary for a human brain, and to inject this into a suitable host germ cell. Such a creature, when implanted and born from a suitable womb, would very possibly be conscious and artificial. But what properties of this organism would be responsible for its consciousness? Could such a being be made from non-biological components? Can, technological technique be used in the design of computers and be to adapt and create a conscious entity? Would it ever be ethical to do such a thing? Neuroscience hypothesizes that consciousness is the synergy generated with the inter-operation of various parts of our brain, what have come to be called the neuronal correlates of consciousness, or NCC. The brain seems to do this while avoiding the problem described in the Homunculus fallacy and overcoming the problems described below in the section on the nature of consciousness. A quest for proponents of artificial consciousness is therefore to manufacture a machine to emulate this inter-operation, which no one yet claims fully to understand.
Consciousness is described at length in the consciousness article in Wikipedia. Wherefore, some informal type of naivete has to the structural foundation of realism and the direct of realism are that we perceive things in the world directly and our brains perform processing. On the other hand, according to indirect realism and dualism our brains contain data about the world that is obtained by processing but what we perceive is some sort of mental model or state that appears to overlay physical things as a result of projective geometry (such as the point observation in Rene Descartes dualism). Which of these general approaches to consciousness is correct has not been resolved and is the subject of fierce debate. The theory of direct perception is problematical because it would seem to require some new physical theory that allows conscious experience to supervene directly on the world outside the brain. On the other hand, if we perceive things indirectly, via a model of the world in our brains, then some new physical phenomenon, other than the endless further flow of data, would be needed to explain how the model becomes experience. If we perceive things directly self-awareness is difficult to explain because one of the principal reasons for proposing direct perception is to avoid Ryle's regress where internal processing becomes an infinite loop or recursion. The belief in direct perception also demands that we cannot 'really' be aware of dreams, imagination, mental images or any inner life because these would involve recursion. Self awareness is less problematic for entities that perceive indirectly because, by definition, they are perceiving their own state. However, as mentioned above, proponents of indirect perception must suggest some phenomenon, either physical or dialyzed to prevent Ryle's regress. If we perceive things indirectly then self awareness might result from the extension of experience in time described by Immanuel Kant, William James and Descartes. Unfortunately this extension in time may not be consistent with our current understanding of physics.
Information processing consists of encoding a state, such as the geometry of an image, on a carrier such as a stream of electrons, and then submitting this encoded state to a series of transformations specified by a set of instructions called a program. In principle the carrier could be anything, even steel balls or onions, and the machine that implement the instructions need not be electronic, it could be mechanical or fluids. Digital computers implement information processing. From the earliest days of digital computers people have suggested that these devices may one day be conscious. One of the earliest workers to consider this idea seriously was Alan Turing. The Wikipedia article on Artificial Intelligence (AI) considers this problem in depth. If technologists were limited to the use of the principles of digital computing when creating a conscious entity, they would have the problems associated with the philosophy of strong AI. The most serious problem is John Searle's Chinese room argument in which it is demonstrated that the contents of an information processor have no intrinsic meaning - at any moment they are just a set of electrons or steel balls etc. Searle's objection does not convince those who believe in direct perception because they would maintain that 'meaning' is only to be found in the objects of perception, which they believe is the world itself. The objection is also countered by the concept of emergence in which it is proposed that some unspecified new physical phenomenon arise in very complex processors as a result of their complexity. It is interesting that the misnomer digital sentience is sometimes used in the context of artificial intelligence research. Sentience means the ability to feel or perceive in the absence of thoughts, especially inner speech. It draws attention to the way that conscious experience is a state rather than a process that might occur in processors.
The debate about whether a machine could be conscious under any circumstances is usually described as the conflict between physicalism and dualism. Dualities believe that there is something nonphysical about consciousness while physicalist hold that all things are physical. Those who believe that consciousness is physical are not limited to those who hold that consciousness is a property of encoded information on carrier signals. Several indirect realist philosophers and scientists have proposed that, although information processing might deliver the content of consciousness, the state that is consciousness be due to another physical phenomenon. The eminent neurologist Wilder Penfield was of this opinion and scientists such as Arthur Stanley Eddington, Roger Penrose, Herman Weyl, Karl Pribram and Henry Stapp among many others, have also proposed that consciousness involve physical phenomena that are more subtle than simple information processing. Even some of the most ardent supporters of consciousness in information processors such as Dennett suggests that some new, emergent, scientific theory may be required to account for consciousness. As was mentioned above, neither the ideas that involve direct perception nor those that involve models of the world in the brain seem to be compatible with current physical theory. It seems that new physical theory may be required and the possibility of dualism is not, as yet, ruled out.
Some technologists working in the field of artificial consciousness are trying to create devices that appear conscious. These devices might simulate consciousness or actually be conscious but provided are those that appear conscious in the desired result that has been achieved. In computer science, the term digital sentience is used to describe the concept of digital numeration could someday be capable of independent thought. Digital sentience, if it ever comes to exist, is likely to be a form of artificial intelligence. A generally accepted criterion for sentience is self-awareness and this is also one of the definitions of consciousness. To support the concept of self-awareness, a definition of conscious can be cited: "having an awareness of one's environment and one's own existence, sensations, and thoughts.” In more general terms, an AC system should be theoretically capable of achieving various or by a more strict view all verifiable, known, objective, and observable aspects of consciousness so that the device appears conscious. Another, but less to agree about, that its responsible and corresponding definition as extracted in the word of “conscious,” slowly emerges as to be inferred through the avenue in being of, "Possessing knowledge by the seismical provisions that allow whether are by means through which ane existently internal and/or externally is given to its observable property, whereas of becoming labelled for reasons that posit in themselves to any assemblage that has forwarded by ways of the conscious experience. Although, the observably existing provinces are those that are by their own nature the given properties from each that occasion to natural properties of a properly ordered approving for which knowledgeable entities must somehow endure to exist in the awarenesses of sensibility.
There are various aspects and/or abilities that are generally considered necessary for an AC system, or an AC system should be able to learn them; These are very useful as criteria to determine whether a certain machine is artificially conscious. These are only the most cited, however, there are many others that are not covered. The ability to predict (or anticipate) foreseeable events is considered a highly desirable attribute of AC by Igor Aleksander: He writes in Artificial Neuro-consciousness: An Update: "Prediction is one of the key functions of consciousness. An organism that cannot predict would have itself its own serious hamper of consciousness." The emergent’s multiple draft’s principle proposed by Daniel Dennett in Consciousness Explained may be useful for prediction: It involves the evaluation and selection of the most appropriate "draft" to fit the current environment. Consciousness is sometimes defined as self-awareness. While self-awareness is very important, it may be subjective and is generally difficult to test. Another test of AC, in the opinion of some, should include a demonstration that machines can learn the ability to filter out certain stimuli in its environment, to focus on certain stimuli, and to show attention toward its environment in general. The mechanisms that govern how human attention is driven are not yet fully understood by scientists. This absence of knowledge could be exploited by engineers of AC; Since we don't understand attentiveness in humans, we do not have specific and known criteria to measure it in machines. Since unconsciousness in humans equates to total inattentiveness, the AC should have outputs that indicate where its attention is focussed at anyone time, at least during the aforementioned test. By Antonio Chella from University of Palermo "The mapping between the conceptual and the linguistic areas gives the interpretation of linguistic symbols in terms of conceptual structures. It is achieved through a focus of attentive mechanistic implementation, by means of suitable recurrent neural networks with internal states. A sequential attentive mechanism is hypothesized that suitably scans the conceptual representation and, according to the hypotheses generated on the basis of previous knowledge, it predicts and detects the interesting events occurring in the scene. Hence, starting from the incoming information, such a mechanism generates expectations and it makes contexts in which hypotheses may be verified and, if necessary, adjusted. "Awareness could be another required aspect. However, again, there are some problems with the exact definition of awareness. To illustrate this point is the philosopher David Chalmers (1996) controversially puts forward the panpsychist argument that a thermostat could be considered conscious: it has states corresponding too hot, too cold, or at the correct temperature. The results of the experiments of neuro-scanning on monkeys suggest that a process, not a state or object activate neurons. For such reaction there must be created a model of the process based on the information received through the senses, creating models in such that its way demands a lot of flexibility, and is also useful for making predictions. Personality is another characteristic that is generally considered vital for a machine to appear conscious. In the area of behavioural psychology, there is a somewhat popular theory that personality is an illusion created by the brain in order to interact with other people. It is argued that without other people to interact with, humans (and possibly other animals) would have no need of personalities, and human personality would never have evolved. An artificially conscious machine may need to have a personality capable of expression such that human observers can interact with it in a meaningful way. However, this is often questioned by computer scientists; The Turing test, which measures by a machine's personality, is not considered generally useful anymore. Learning is also considered necessary for AC. By engineering consciousness, a summary by Ron Chrisley, studying at the University of Sussex, says that of consciousness is and involves self, transparency, learning (of dynamics), planning, heterophenomenology, split of attentional signal, action selection, attention and timing management. Daniel Dennett said in his article "Consciousness in Human and Robotic Minds" are said that, "It might be vastly easier to make an initial unconscious or nonconscious "infant, as a, robot and let it "grow up" into consciousness, is more or less the way we all do. Chrisley explained that the robot Cog, is easily described, "Will did not bring about the adult at first, in spite of its adult size. But it is being designed to pass through an extended period of artificial infancy, during which it will have to learn from experience, experience it will gain in the rough-and-tumble environment of the real world, and in addition, ‘nobody doubts that any agent capable of interacting intelligently with a human being on human terms must have access too literally millions if not billions of logically independent items of world knowledge. In that of either of these must be hand-coded individually by human programmers-a tactic being pursued, notoriously, by Douglas Lenat and his CYC team in Dallas-or some way must be found for the artificial agent to learn its world knowledge from (real) interactions with the (real) world. An interesting article about learning is Implicit learning and consciousness by Axel Cleeremans, University of Brussels and Luis JimĂ©nez, University of Santiago, where learning is defined as “a set of phylogenetically advanced adaptation processes that critically depend on an evolved sensitivity to subjective experience so as to enable agents to afford flexible control over their actions in complex, unpredictable environments. Anticipation is the final characteristic that could possibly be used to make a machine appear conscious. An artificially conscious machine should be able to anticipate events correctly in order to be ready to respond to them when they occur. The implication here is that the machine needs real-time components, making it possible to demonstrate that it possesses artificial consciousness in the present and not just in the past. In order to do this, the machine being tested must operate coherently in an unpredictable environment, to simulate the real world.
Newborn babies have been trying for centuries to convince us they are, like the rest of us, sensing, feeling, thinking human beings. Struggling by implies of its position, but now seems as contrary to thousands of years of ignorant supposition that newborns are partly human, sub-human, or not-yet human, the vast majority of babies arrive in hospitals today, greeted by medical specialists who are still sceptical as to whether they can actually see, feel pain, learn, and remember what happens to them. Physicians, immersed in protocol, employ painful procedures, confident no permanent impression, certainly no lasting damage, will result from the manner in which babies are received into this world.
The way "standard medicine" sees infants-by no means universally shared by women or by the midwives who used to assist them at birth-has taken on increasing importance in a country where more than 95% are hospitals born and a quarter of these surgically delivered. While this radical change was occurring, the psychological aspects of birth were little considered. In fact, for most of the century, medical beliefs about the infants nervous system prevailed in psychology as well. However, in the last three decades, research psychology has invested heavily in infant studies and uncovered many previously hidden talents of both the fetus and the newborn baby. The findings are surprising: Babies are more sensitive, more emotional, and more cognitive than we used to believe. They are not what we thought. Babies are so different that we must create new paradigms to describe accurately who they are and what they can do.
Not long ago, experts in pediatrics and psychology were teaching that babies were virtually blind, had no sense of colour, could not recognize their mothers, and heard in "echoes.” They believed babies cared little about sharp changes in temperature at birth and had only a crude sense of smell and taste. Their pain was "not like our pain" yet, their cries not meaningful, their smiles were "gas," and their emotion’s undeveloped. Worst of all, most professionals believed babies were not equipped with enough brain matter to permit them to remember, learn, or find meaning in their experiences.
These false and unflattering views are still widely spread between both professionals and the public. No wonder people find it hard to believe that a traumatic birth, whether it is by cesarean section or vaginal, has significant, on-going effects.
Unfortunately, today these unfounded prejudices still have the weight of "science" behind them, but the harmful results to babies are hardly better than the rank superstitions of the past. The resistance of "experts" who continue to see infants in terms of their traditional incapacities may be the last great obstacle for babies to leap over before being embraced for whom they really are. Old ideas are bound to die under the sheer weight of new evidence, but not before millions of babies suffer unnecessarily because their parents and their doctors do not know they are fully human.
As the light of research reaches into the dark corners of prejudice, we may thank those in the emerging field of prenatal/perinatal psychology. Since this field is often an enter professional collaboration and does not fit conveniently to accepted academic departments, the field is not yet recognized in the academic world by endowed chairs or even by formal courses. At present only a few courses exist throughout the world. Yet research teams have achieved a succession of breakthroughs that challenge standard "scientific" ideas of human development.
Scholars in this field respect the full range of evidence of infant capabilities, whether from personal reports contributed by parents, revelations arising from therapeutic work, or from formal experiments. Putting together all the bits and pieces of information gathered from around the globe yields a fundamentally different picture of a baby.
The main way information about sentient, conscious babies has reached the public, especially pregnant parents, has been via popular media: books, movies, magazine features, and television. Among the most outstanding have been The Secret Life of the Unborn Child by Canadian psychiatrist Thomas Verny (now in 25 languages), movies like Look Who's Talking, and several talk shows, including Oprah Winfrey, where a program on therapeutic treatment of womb and birth traumas probably reached 25 million viewers in 25 countries. Two scholarly journals are devoted entirely to prenatal/perinatal psychology, one in North America that began in 1986, and one in Europe beginning in 1989. The Association for Pre- and Perinatal Psychology and Health (APPPAH) is a gathering place for people interested in this field and who keep informed through newsletters, journals, and conferences.
Evidence that babies are sensitive, cognitive, and are affected by their birth experiences may come from various sources. The oldest evidence is anecdotal and intuitive. Mothers are the principal contributors to the idea of baby as a person, one you can talk to, and one who can talk back as well. This process, potentially available to any mother, is better explained in psychic terms than in word-based language. This exchange of thoughts is probably telepathic rather than linguistic.
Mothers who communicate with their infants know that the baby is a person, mind and soul, with understanding, wisdom, and purpose. This phenomenon is cross-cultural, probably universal, although all mothers do not necessarily engage in this dialogue. In an age of "science," a mother's intuitive knowledge is too often dismissed. What mothers know has not been considered as valid data. What mothers say about their infants must be venal, self-serving, or imaginary, and can never be equal to what is known by "experts" or "scientists."
This prejudice extends into a second category of information about babies, and the evidence derived from clinical work. Although the work of psychotherapy is usually done by formally educated, scientifically trained, licensed persons who are considered expert in their field, the information they listen to is anecdotal and their methods are the blending of science and art.
Their testimony of infant intelligence, based on the recollections of clients, is often compelling. Therapists are privy to clients' surprising revelations, many of which show a direct connection between traumas surrounding birth and later disabilities of heart and mind. Although it is possible for these connections to be purely imaginary, we know they are not when hospital records and eyewitness reports confirm the validity of the memories. Obstetrician David Cheek, using hypnosis with a series of subjects, discovered that they could accurately report the full set of left and right turns and sequences involved in their own deliveries. This is technical information that no ordinary person would have unless his memories are accurate.
Psychologists using hypnosis, have found it necessary to test the reliability of memories people gave me about their traumas during the birth process, memories that had not previously been conscious. I hypnotized mother and child pairs who said they had never spoken in any detail about that child's birth. I received a detailed report of what happened from the now-adult child that I compared with the mother's report, given also in hypnosis.
The reports dovetailed at many points and were clearly reports of the same birth. By comparing one story with the other, I could see when the adult child was fantasizing, rather than having accurate recall, but fantasy was rare. It is to conclude that these birth memories were real memories, and were a reliable guide to what had happened.
Some of the first indications that babies are sentient came from the practice of psychoanalysis, stretching back to the beginning of the century to the pioneering work of Sigmund Freud. Although Freud himself was sceptical about the operation of the infant mind, his clients kept bringing him information that seemed to link their anxieties and fears to events surrounding their births. He theorized that birth might be the original trauma upon which later anxiety was constructed.
Otto Rank, Freud's associate, was more certain that birth traumas underlay many later neuroses, so he reorganized psychoanalysis around the assumption of birth trauma. He was rewarded by the rapid recovery of his clients who were "cured" in far less time than was required for a customary psychoanalysis. In the second half of the century, important advances have been made in resolving early trauma and memories of trauma.
Hypnotherapy, primal therapy, psychedelic therapies, various combinations of body work with breathing and sound stimulation, sand tray therapy, and art effects have all proved useful in accessing important imprints, decisions, and memories stored by the infant mind. If there had been no working mind in infancy, of course there would be no need to return to it to heal bad impressions, change decisions, and otherwise resolve mental and emotional problems.
A third burgeoning source of information about the conscious nature of babies comes from scientific experiments and systematic observations utilizing breakthrough technologies. In our culture, with its preference for refined measurement and strict protocols, these are the studies that get funding. And the results are surprising from this contemporary line of empirical research.
We have learned so much about babies in the last twenty years that most of what we thought we knew before is suspect, and much of it is obsolete. I will highlight the new knowledge in three sections: development of the physical senses, beginnings of self-expression, and evidence of active mental life.
First, we have a much better idea of our physical development, the process of the embodiment from conception to birth. Our focus here is on the senses and when they become available during gestation. Touch is our first sense and perhaps our last. Sensitivity to touch begins in our faces about seven weeks gestational age. Tactile sensitivity expands steadily to include most parts of the fetal body by 17 weeks. In the normal womb, touch is never rough, and temperature is relatively constant. At birth, this placid environment ends with dramatic new experiences of touch that no baby can overlook.
By only 14 weeks gestational age, the taste buds are formed, and ultrasound shows both sucking and swallowing. A fetus controls the frequency of swallowing amniotic fluid, and will speed up or slow in reaction to sweet and bitter tastes. Studies show babies have a definite preference for sweet tastes. Hearing begins earlier than anyone thought possible at 16 weeks. The ear is not complete until about 24 weeks, a fact revealing the complex nature of listening, which includes reception of vibes through our skin, skeleton, and vestibular system as well as the ear. Babies in the womb are listening to maternal sounds and to the immediate environment for almost six months. By birth, their hearing is about as good as ours.
Our sense of sight also develops before birth, although our eyelids remain fused from week 10 through 26. Nevertheless, babies in the womb will react to light flashed on the mother's abdomen. By the time of birth, vision is well-advanced, though not yet perfect. Babies have no trouble focussing at the intimate 16-inch distance where the faces of mothers and fathers are usually found.
Mechanisms for pain perception like those for touch, develop early. By about three month, if babies are accidentally struck by a needle inserted into the womb to withdraw fluid during amniocentesis, they quickly twist away and try to escape from the needle. Intrauterine surgery, a new aspect of fetal medicine made possibly in part by our new ability to see inside the womb, means new opportunities for fetal pain.
Although surgeons have long denied prenates experience pain, a recent experiment in London proved unborn babies feel pain. Babies who were needled for intrauterine transfusions showed a 600% increase in beta-endorphins, hormones generated to deal with stress. In just ten minutes of needling, even 23 week old fetuses were mounting a full-scale stress response. Needling at the intrahapatic vein provokes vigorous body and breathing movements.
Finally, our muscle systems develop under buoyant conditions in the fluid environment of the womb and are regularly used in navigating the area. However, after birth, in the dry world of normal gravity, our muscle systems look feeble. As everyone knows, babies cannot walk, and they struggle, usually in vain, to hold up their own heads. Because the muscles are still relatively undeveloped, babies give a misleading appearance of incompetence. In truth, babies have remarkably useful sensory equipment very much like our own.
A second category of evidence for baby consciousness comes from empirical research on bodily movement in utero. Except for the movement a mother and father could sometimes feel, we have had almost no knowledge of the extent and variety of movement inside the womb. This changed with the advent of real-time ultrasound imaging, giving us moment by moment pictures of fetal activity.
One of the surprises is that movement commences between eight and ten weeks gestational age. This has been determined with the aid of the latest round of ultrasound improvements. Fetal movement is voluntary, spontaneous, and graceful, not jerky and reflexive as previously reported. By ten weeks, babies move their hands to their heads, face, and mouth; they flex and extend their arms and legs; They open and close their mouths and rotate longitudinally. From 10 to 12 weeks onward, the repertoire of body language is largely complete and continues throughout gestation. Periodic exercise alternates with rest periods on a voluntary basis reflecting individual needs and interests. Movement is self-expression and expressional personalities.
Twins viewed periodically via ultrasound during gestation often show highly independent motor profiles, and, over time continue to distinguish themselves through movement both inside and outside the womb. They are expressing their individuality.
Close observation has brought many unexpected behaviours to light. By 16 weeks, male babies are having their first erections. As soon as they have hands, they are busy exploring everywhere and everything, feet, toes, mouth, and the umbilical cord: these are their first toys.
By 30 weeks, babies have an intense dream life, spending more time in the dream state of sleep than they ever do after they are born. This is significant because dreaming is definitely a cognitive activity, a creative exercise of the mind, and because it is a spontaneous and personal activity.
Observations of the fetus also reveal a number of reactions to conditions in the womb. Such are the reactions to provocative circumstances is a further sign of selfhood. Consciousness of danger and manoeuver of the self-defence are visible in fetal reactions to amniocentesis. Even when things go normally and babies are not struck by needles, they react with wild variations of normal heart activity, alter their breathing movements, may "hide" from the needle, and often remain motionless for a time - suggesting fear and shock.
Babies react with alarm to loud noises, car accidents, earthquakes, and even to their mother's watching terrifying scenes on television. They swallow less when they do not like the taste of amniotic fluid, and they stop their usual breathing movements when their mothers drink alcohol or smoke cigarettes.
In a documented report of work via ultrasound, a baby struck accidentally by a needle not only twisted away, but located the needle barrel and collide repeatedly-surely an aggressive and angry behaviours. Similarly, ultrasound experts have reported seeing twins hitting each other, while others have seen twins playing together, gently awakening one-another, rendering cheek-to-cheek, and even kissing. Such scenes, some at only 20 weeks, were never anticipated in developmental psychology. No one anticipated sociable behaviour nor emotional behaviour until months after a baby's birth.
We can see emotion expressed in crying and smiling long before 40 weeks, the usual time of birth. We see first smiles on the faces of premature infants who are dreaming. Smiles and pleasant looks, along with a variety of unhappy facial expressions, tell us dreams have pleasant or unpleasant contents to which babies are reacting. Mental activity is causing emotional activity. Audible crying has been reported by 23 weeks, in cases of abortion, revealing that babies are experiencing very appropriate emotion by that time. Close to the time of birth, medical personnel have documented crying from within the womb, in association with obstetrical procedures that have allowed air to enter the space around the fetal larynx.
Finally, a third source of evidence for infant consciousness is the research that confirms various forms of learning and memory both in the fetus and the newborn. Since infant consciousness was considered impossible until recently, experts have had to accept a growing body of experimental findings illustrating that babies learn from their experiences. In studies that began in Europe in 1925 and America in 1938, babies have demonstrated all the types of learning formally recognized in psychology at the time: classical conditioning, habituation, and reinforcement conditioning, both inside and outside the womb.
In modern times, as learning has been understood more broadly, experiments have shown a range of learning abilities. Immediately after birth, babies show recognition of musical passages, which they have heard repeatedly before birth, whether it is the bassoon passage in Peter and the Wolf, "Mary Had a Little Lamb," or the theme music of a popular soap opera.
Language acquisition begins in the womb as babies listen repeatedly to their mothers' intonations and learn their mother tongue. As early as 25 weeks, the recording of a baby's first cry contains so many rhythms, intonations, and other features common to their mother's speech that their spectrographs can be matched. In experiments shortly after birth, babies recognize their mother's voice and prefer her voice to other female voices. In the delivery room, babies recognize their father's voice and recognize specific sentences their fathers have spoken, especially if the babies have heard these sentences frequently while they were in the womb. After birth, babies show special regard for their native language, preferring it to a foreign language.
Fetal learning and memory also consist of stories that are read aloud to them repeatedly before birth. At birth, babies will alter their sucking behaviour to obtain recordings of the familiar stories. In a recent experiment, a French and American team had mothers repeat a particular children's rhyme each day from week 33 to week 37. After four weeks of exposure, babies reacted to the target rhymes and not to other rhymes, proving they recognize specific language patterns while they are in the womb.
Newborn babies quickly learn to distinguish their mother's face from other female faces, their mother's breast pads from other breast pads, their mother's distinctive underarm odour, and their mother's perfume if she has worn the same perfume consistently.
Premature babies learn from their unfortunate experiences in neonatal intensive care units. One boy, who endured surgery parlayed with curare, but was given no pain-killing anaesthetics, of developed and pervading fear of doctors and hospitals that remains undiminished in his teens. He also learned to fear the sound and sight of adhesive bandages. This was in reaction to having some of his skin pulled off with adhesive tape during his stay in the premature nursery.
Confirmation that early experiences of pain have serious consequences later has come from recent studies of babies at the time of first vaccinations. Researchers who studied infants being vaccinated four to six months after birth discovered that babies who had experienced the pain of circumcision had higher pain scores and cried longer. The painful ordeal of circumcision had apparently conditioned them to pain and set their pain threshold lower. This is an example of learning from experience: Perinatal pain.
Happily, there are other things to learn besides pain and torture. The Prenatal Classroom is a popular program of prenatal stimulation for parents who want to establish strong bonds of communication with a baby in the womb. One of the many exercises is the "Kick Game," which you play by responding to the child's kick by touching the spot your baby just kicked, and saying "kick, baby kick." Babies quickly learn to respond to this kind of attention: They do kick again and they learn to kick anywhere their parents touch. One father taught his baby to kick in a complete circle.
Babies also remember consciously the big event of birth itself, at least during the first years of their lives. Proof of this comes from little children just learning to talk. Usually around two or three years of age, when children are first able to speak about their experiences, some spontaneously recall what their birth was like. They tell what happened in plain language, sometimes accompanied by pantomime, pointing and sound effects. They describe water, black and red colours, the coming light, or dazzling light, and the squeezing sensations. Cesarean babies tell about a door or window suddenly opening, or a zipper that zipped open and let them out. Some babies remember fear and danger. They also remember and can reveal secrets.
One of my favourite stories of a secret birth memory came from Cathy, a midwife's assistant. With the birth completed, she found herself alone with a hungry, restless baby after her mother had gone to bathe and the chief midwife was busy in another room. Instinctively, Cathy offered the baby her own breast for a short time: then she wondered if this were appropriate and stopped feeding the infant without telling anyone what had happened. Years later, when the little young woman was almost four, Cathy was babysitting her. In a quiet moment, she asked the child if she remembered her birth. The child did, and volunteered various accurate details. Then, moving closer to whisper a secret, she said "You held me and gave me titty when I cried, and Mommy wasn't there." Cathy said to herself, "Nobody can tell me babies don't remember their births"
Is a baby a conscious and real person? To me it is no longer appropriate to speculate. It is too late to speculate when so much is known. The range of evidence now available in the form of knowledge of the fetal sensory system, observations of fetal behaviour in the womb, and experimental proof of learning and memory - all of this evidence-amply verifies what some mothers and fathers have sensed from time immemorial, that a baby is a real person. The baby is real in having a sense of self that can be seen in creative efforts to adjust or to influence its environment. Babies show self-regulation (as in restricting swallowing and breathing), the self-defence (as in retreating from invasive needles and strong light), self-assertion, combat with a needle, or striking out at a bothersome twin.
Babies are like us in having clearly manifested feelings in their reactions to assaults, injuries, irritations, or medically inflicted pain. They smile, cry, and kick in protest, manifest fear, anger, grief, pleasure, or displeasure in ways that seem entirely appropriate in relation to their circumstances. Babies are cognitive beings, thinking their own thoughts, dreaming their own dreams, learning from their own experiences, and remembering their own experiences.
An iceberg can serve as a useful metaphor to understand the unconscious mind, its relationship to the conscious mind and how the two parts of our mind can better work together. As an iceberg floats in the water, the huge mass of it remains below the surface.
Only a small percentage of the whole iceberg is visible above the surface. In this way, the iceberg is like the mind. The conscious mind is what we notice above the surface while the unconscious mind, the largest and most powerful part, remains unseen below the surface.
In our metaphor that regards of the small amount of icebergs, far and above the surface represents the conscious mind; The huge mass below the surface, the unconscious mind. The unconscious mind holds all awareness that is not presently in the conscious mind. All memories, feelings and thoughts that are out of conscious awareness are by definition "unconscious." It is also called the subconscious and is known as the dreaming mind or deep mind.
Knowledgeable and powerful in a different way than the conscious mind, the unconscious mind handles the responsibility of keeping the body running well. It has memory of every event we've ever experienced; it is the source and storehouse of our emotions; and it is often considered our connection with Spirit and with each other.
No model of how the mind works disputes, the tremendous power, which is in constant action below the tip of the iceberg. The conscious mind is constantly supported by unconscious resources. Just think of all the things you know how to do without conscious awareness. If you drive, you use more than 30 specific skills . . . without being aware of them. These are skills, not facts; they are processes, requiring intelligence, decision-making and training.
Besides these learned resources that operate below the surface of consciousness there are important natural resources. For instance, the unconscious mind regulates all the systems of the body and keeps them in harmony with each other. It controls heart rate, blood pressure, digestion, the endocrine system and the nervous system, just to name a few of its natural, automatic duties.
The conscious mind, like the part of the iceberg above the surface, is a small portion of the whole being. The conscious mind is what we ordinarily think of when we say "my mind." It's associated with thinking, analysing and making judgments and decisions. The conscious mind is actively sorting and filtering its perceptions because only so much information can reside in consciousness at once. Everything else falls back below the water line, into unconsciousness.
Only seven bits of information, and/or minus two can be held consciously at one time. Everything else we are thinking, feeling or perceiving now . . . along with all our memories remains unconscious, until called into consciousness or until rising spontaneously.
The imagination is the medium of communication between the two parts of the mind. In the iceberg metaphor, the imagination is at the surface of the water. It functions as a medium through which content from the unconscious mind can come into conscious awareness.
Communication through the imagination is two-way. The conscious mind can also use the medium of the imagination to communicate with the unconscious mind. The conscious mind sends suggestions about what it wants through the imagination to the unconscious. It imagines things, and the subconscious intelligencer work to make them happen.
The suggestions can be words, feelings or images. Athletes commonly use images mentally to rehearse how they want to perform by picturing themselves successfully completing their competition. A tennis player may see a tennis ball striking the racket at just the right spot, at just the perfect moment in the swing. Studies show that this form of imaging improves performance.
However, the unconscious mind uses the imagination to communicate with the conscious mind far more often than the other way around. New ideas, hunches, daydreams and intuitions come from the unconscious to the conscious mind through the medium of the imagination.
An undeniable example of the power in the lower part of the iceberg is dreaming. Dream images, visions, sounds and feelings come from the unconscious. Those who are aware of their dreams know how rich and real they can be. Even filtered, as they are when remembered later by the conscious mind, dreams can be quite powerful experiences.
Many people have received workable new ideas and insights, relaxing daydreams, accurate hunches, and unexpected intuitive understandings by replaying their dreams in a waking state. These are everyday examples of what happens when unconscious intelligencer and processes communicate through the imagination with the conscious mind.
Unfortunately, the culture has discouraged us from giving this information credibility. "It's just, but your imagination" is a commonly heard dismissal of information coming from the deep mind. This kind of conditioning has served to keep us disconnected from the deep richness of our vast unconscious resources.
In the self-healing work we'll be using the faculty of the imagination in several ways. In regression processes to access previously unconscious material from childhood, perinatal experiences and past lives, and even deeper realms of the "universal unconscious." Inner dialogue is another essential tool that makes use of the imagination in process work.
To shoulder atop the iceberg metaphor forward, each of us can be represented an iceberg, with the larger part of ourselves remain deeply submerged. And there's a place in the depths where all of our icebergs come together, a place in the unconscious where we connect with each other
The psychologist Carl Jung has named this realm the "Collective Unconscious." This is the area of mind where all humanity shares experience, and from where we draw on the archetypal energies and symbols that are common to us all. "Past life" memories are drawn from this level of the unconscious.
Another, even deeper level can be termed the "Universal Unconscious" where experiences beyond just humanity's can also be accessed with regression process. It is at this level that many "core issues" begin, and where their healing needs to be accomplished.
The unconscious connection "under the iceberg" between people is often more potent than the conscious level connection, and important consideration in doing the healing work. Relationship is an area rich with triggers to deeply buried material needing healing. And some parts of us cannot be triggered in any way other than "under the iceberg."
Although the conscious mind, steeped in cognition and thought, is able to deceive another . . . the unconscious mind, based in feeling, will often give us information from under the iceberg that contradicts what is being communicated consciously.
"Sounds right but feels wrong," is an example of information from under the iceberg surfacing in the conscious mind, but conflicting with what the conscious mind was ably to attain of its own. This kind of awareness is also called "intuition."
Intuitive information comes without a searching of the conscious memory or a formulation to be filled by imagination. When we access the intuition, we seem to arrive at an insight by a path from unknown sources directly to the conscious awareness. Wham! Out of nowhere, in no time.
No matter what the precise neurological process, the ability to access and use information from the intuition is extremely valuable in the effective and creative use of the tools of self healing. In relating with others, it's important to realize that your intuition will bring you information about the other and your relationship from under the iceberg.
When your intuition is the source of your words and actions, they are usually much more appropriate and helpful than what thinking or other functions of the conscious mind could muster. What you do and say from the intuition in earnest communication will be meaningful to the other, even though it may not make sense to you.
The most skilful and comprehending way to nurture and develop your intuition is to trust all of your intuitive insights. Trust encourages the intuition to be more present. Its information is then more accessible and the conscious mind finds less reason to question, analyse or judge intuitive insights.
The primary skills needed for easy access and trust of intuitive information are: (1) The ability to get out of the way. (2) The ability to accept the information without judgment.
Two easy ways to access intuition and help the conscious mind get out of the way occur: (3) Focus your attention in your abdominal area and imagine you have a "belly brain.” As you feel into and sense this area, "listen" to what your belly brain has to say. This is often referred to as listening to our "gut feelings." (4) With your eyes looking down and to your left and slightly de focussed, simply feel into what to say next.
Once the intuition is flowing, it will continue easily, unless it is Formed. The most usual Formage is for which we may become of, and only because the conscious mind's finds within to all judgments of the intuitive information. The best way to avoid this is to get the cooperation of the conscious mind so it will step aside and become the observer when intuition is being accessed. Cosmic Consciousness is an ultra high state of illumination in the human Mind that is beyond that of "self-awareness," and "ego-awareness." In the attainment of Cosmic Consciousness, the human Mind has entered a state of Knowledge instead of mere beliefs, a state of "I know," instead of "I believe." This state of Mind is beyond that of the sense reasoning in that it has attained an awareness of the Universe and its relation to being and a recognition of the Oneness in all things that is not easily shared with others who have not personally experienced this state of Mind. The attainment of Cosmic illumination will cause an individual to seek solitude from the multitude, and isolation from the noisy world of mental pollution.
Carl Jung was a student and follower of Freud. He was born in a small town in Switzerland in 1875 and all his life was fascinated by folk tales, myths and religious stories. Nonetheless, he had a close friendship with Freud early in their relationship, his independent and questioning mind soon caused a break.
Jung did not accept Freud’s contention that the primary motivations behind behaviour was sexual urges. Instead of Freud’s instinctual drives of sex and aggression, Jung believed that people are motivated by a more general psychological energy that pushes them to achieve psychological growth, self-realization, psychic wholeness and harmony. Also, unlike Freud, he believed that personality continues to develop throughout the lifespan.
It is for his ideas of the collective unconscious that students of literature and mythology are indebted to Jung. In studying different cultures, he was struck by the universality of many themes, patterns, stories and images. These same images, he found, frequently appeared in the dreams of his patients. From these observations, Jung developed his theory of the collective unconscious and the archetypes.
Like Freud, Jung posited the existence of a conscious and an unconscious mind. A model that psychologists frequently use here is an iceberg. The part of the iceberg that is above the surface of the water is seen as the conscious mind. Consciousness is the part of the mind we know directly. It is where we think, feel, sense and intuit. It is through conscious activity that the person becomes an individual. It’s the part of the mind that we “live in” most of the time, and contains information that is in our immediate awareness, the level of the conscious mind, and the bulk of the ice berg, is what Freud would call the unconscious, and what Jung would call the “personal unconscious.” Here we will find thoughts, feelings, urges and other information that is difficult to bring to consciousness. Experiences that do not reach consciousness, experiences that are not congruent with whom we think we are, and things that have become “repressed” would make up the material at this level. The contents of the personal unconscious are available through hypnosis, guided imagery, and especially dreams. Although not directly accessible, material in the personal unconscious has gotten there sometime during our lifetime. For example, the reason you are going to school now, why you picked a particular shirt to wear or your choice of a career may be a choice you reached consciously. But it is also possible that education, career, or clothing style has been influenced by a great deal of unconscious material: Parents’ preferences, childhood experiences, even movies you have seen but about which you do not think when you make choices or decisions. Thus, the depth psychologist would say that many decisions, indeed some of the most important ones that have to do with choosing a mate or a career, are determined by unconscious factors. But still, material in the personal unconscious has been environmentally determined.
The collective unconscious is different. It’s like eye colour. If someone were to ask you, “How did you get your eye colour,” you would have to say that there was no choice involved – conscious or unconscious. You inherited it. Material in the collective unconscious is like a dramatization for this as self bequeathed. It never came from our current environment. It is the part of the mind that is determined by heredity. So we inherit, as part of our humanity, a collective unconscious; the mind is pre-figured by evolution just as is the body. The individual is linked to the past of the whole species and the long stretch of evolution of the organism. Jung thus placed the psyche within the evolutionary process.
What’s in the collective unconscious? Psychological archetypes. This idea of psychological archetypes is among Jung’s most important contributions to Western thought. An ancient idea somewhat like Plato’s idea of Forms or “patterns” in the divine mind that determine the form material objects will take, and the archetype is in all of us. The word “archetype” comes from the Greek “Arche” meaning first, and type meant to “imprinting or patterns.” Psychological archetypes are thus first prints, or patterns that form the basic blueprint for major dynamic counterparts of the human personality. For Jung, archetypes pre-exist in the collective unconscious of humanity. They repeat themselves eternally in the psyches of human beings and they determine how we both perceive and behave. These patterns are inborn within us. They are part of our inheritance as human beings. They reside as energy within the collective unconscious and are part the psychological life of all peoples everywhere at all times. They are inside us and they are outside us. We can meet them by going inward to our dreams or fantasies. We can meet them by going outward to our myths, legends, literature and religions. The archetype can be a pattern, such as a kind of story. Or it can be a figure, such as a kind of character.
In her book Awakening the Heroes Within, Carolyn Pearson identifies twelve archetypes that are fairly easy to understand. These are the Innocent, the Orphan, the Warrior, the Caregiver, the Seeker, the Destroyer, the Lover, the Creator, the Ruler, the Magician, the Sage, and the Fool. If we look at art, literature, mythology and the media, we can easily identify some of these patterns. One familiarized is the contemporary western culture is the Warrior. We find the warrior myth encoded in all the great heroes whoever took on the dragon, stood up to the tyrant, fought the sorcerer, or did battle with the monster: And in so doing rescued himself and others. The true Warrior is not just overbearing. The aggressive man (or women) fights to feel superior to others, to keep them down. The warrior fights to protect and ennoble others. The warrior protects the perimeters of the castle or the family or the psyche. The warrior’s myth is active in each of us any time we stand up against unfair authority, be it a boss, teacher or parent. The highest level warrior has at some time confronted his or her own inner dragons. We see the Warrior’s archetype in the form of pagan deities, for example the Greek god of war, Mars. David, who fights Goliath, or Michael, who casts Satan out of Heaven is familiar Biblical warrior. Hercules, Xena (warrior princess) and Conan the Barbarian are more contemporary media forms the warrior takes. And it is in this widely historical variety that we can find an important point about the archetype. It really is unconscious. The archetype is like the invisible man in famous story. In the story, a man invents a potion that, when ingested, renders him invisible. He becomes visible only when he puts on clothes. The archetype is like this. It remains invisible until it unfolds within the Dawn of its particular culture: in the Middle Ages this was King Arthur; in modern America, it may be Luke Skywalker. But if the archetype were not a universal pattern imprinted on our collective psyche, we would not be able to continue to recognize it over and over. The love goddess is another familiar archetypal pattern. Aphrodite to the Greeks, Venus to the Romans, she now appears in the form of familiar models in magazines like “Elle” and “Vanity Fair.” And whereas in ancient Greece her place of worship was the temple, today is it the movie theatre and the cosmetics counter at Nordstrom’s. The archetype remains; the garments it dawns are those of its particular time and place.
This brings us to our discussion of the Shadow as archetype. The clearest and most articulate discussion of this subject is contained in Johnson’s book Owning Your Own Shadow. The Shadow is not a difficult concept. It is merely the “dark side” of the psyche. It’s everything that doesn’t fit into the Persona. The word “persona” comes from the theatre. In the Roman theatre, characters would put on a mask that represented who the character was in the drama. The word “persona” literally means “mask.” Johnson says that the persona is how we would like to be seen by the world, a kind of psychological clothing that “mediates between our true elves and our environment” in much the same way that clothing gives an image. The Shadow is what doesn’t fit into this Persona. These “refused and unacceptable” characteristics don’t go away; They are stuffed or repressed and can, if unattended to, begin to take on a life of their own. One Jungian likens the process to that of filling a bag. We learn at a very young age that there are certain ways of thinking, being and relating that are not acceptable in our culture, and so we stuff them into the shadow bag. In our Western culture, particularly in the United States, thoughts about sex are among the most prevalent that are unacceptable and so sex gets stuffed into the bag. The shadow side of sexuality is quite evident in our culture in the form of pornography, prostitution, and topless bars. Psychic energy that is not dealt within a healthy way takes a dark or shadow form and begins to take on a life of its own. As children our bag is fairly small, but as we get older, it becomes larger and more difficult to drag.
Therefore, it is not difficult to see that there is a shadow side to the Archetypes discussed earlier. The shadow side to the warrior is the tyrant, the villain, the Darth Vader, who uses his or her skills for power and ego enhancement. And whereas the Seeker Archetype quests after truth and purity, the shadow Seeker is controlled by pride, ambition, and addictions. If the Lover follows his/her bliss, commits and bonds, the shadow lover signifies a seducer a sex addict or interestingly enough, a puritan.
But we can use the term “shadow” in a more general sense. It is not merely the dark side of a particular archetypal pattern or form. Wherever Persona is, Shadow is also. Wherever good is, is evil. We first know the shadow as the personal unconsciousness, for in all that we abhor, deny and repressing power, greed, cruel and murderous thoughts, unacceptable impulses, morally and ethically wrong actions. All the demonic things by which human beings betray their inhumanity to other beings are shadow. Shadow is unconscious. This is a very important idea. Since it is unconscious, we know it only indirectly, projection, just as we know the other Archetypes of Warrior, Seeker and Lover. We encounter the shadow in other people, things, and places where we project it. The scape goat is a perfect example of shadow projection. The Nazi’s projection of shadow onto the Jews gives us some insight into how powerful and horrific the archetype is. Jung says that when you are in the grips of the archetype, you don’t have it, it has you.
This idea of projection raises an interesting point. It means that the shadow stuff isn’t “out there” at all; it is really “in here”; that is inside us. We only know it is inside us because we see it outside. Shadow projections have a fateful attraction to us. It seems that we have discovered where the bad stuff really is: in him, in her, in that place, there! There it is! We have found the beast, the demon, the bad guy. But does Obscenity really exist, or is what we see as evil all merely projection of our own shadow side? Jung would say that there really is such a thing as evil, but that most of what we see as evil, particularly collectively, is shadow projection. The difficulty is separating the two. And we can only do that when we discover where the projection ends. Hence, Johnson’s book title “Owning Your own Shadow.”
Amid all the talk about the "Collective Unconscious" and other sexy issues, most readers are likely to miss the fact that C.G. Jung was a good Kantian. His famous theory of Synchronicity, "an accusal connecting principle," is based on Kant's distinction between phenomena and things-in-themselves and on Kant's theory that causality will not operate among thing-in-themselves the way it does in phenomena. Thus, Kant could allow for free will (unconditioned causes) among things-in-themselves, as Jung allows for synchronicity ("meaningful coincidences"). Next to Kant, Jung is close to Schopenhauer, praising him as the first philosopher he had read, "who had the courage to see that all was not for the best in the fundamentalists of the universe" [Memories, Dreams, Reflections, p. 69]. Jung was probably unaware of the Friesian background of Otto's term "numinosity" when he began to use it for his Archetypes, but it is unlikely that he would object to the way in which Otto's theory, through Fries, fits into Kantian epistemology and metaphysics.
Jung's place in the Kant-Friesian tradition is on a side that would have been distasteful to Kant, Fries, and Nelson, whose systems were basically rationalistic. Thus Kant saw religion as properly a rational expression of morality, and Fries and Nelson, although allowing an aesthetic content to religion different from morality, nevertheless did not expect religion to embody much more than good morality and good art. Schopenhauer, Otto, and Jung all represent an awareness that more exists to religion and to human psychological life than this. The terrifying, uncanny, and fascinating elements of religion and ordinary life are beneath the notice of Kant, Fries, and Nelson, while they are indisputable and irreducible elements of life, for which there must be an account, with Schopenhauer, Otto, and Jung. As Jung once, again said of Schopenhauer: "He was the first to speak of the suffering of the world, which visibly and glaringly surrounds us, and of confusion, passion, evil - all those things that the others hardly seemed to notice and always tried to resolve into all-embracing harmony and comprehensibility." It is an awareness of this aspect of the world that renders the religious ideas of "salvation" meaningful; yet "salvation" as such is always missing from moralistic or aesthetic renderings of religion. Only Jung could have written his Answer to Job.
Jung's great Answer to Job, indeed, represents an approach to religion that is all but unique. Placing God in the Unconscious might strike most people as reducing him to a mere psychological object; Nevertheless, that is to overlook Jung's Kantianism. The unconscious, and especially the Collective Unconscious, belongs to Kantian things-in-themselves, or to the transcendent Will of Schopenhauer. Jung was often at pains not to complicate his theory of the Archetypes by committing himself to a metaphysical theory - he wanted the theory to work whether he was talking about the brain or about the Transcendent - but that was merely a concession to the materialistic bias of contemporary science. He had no materialistic commitment himself and, when it came down to it, was not going to accept such naive reductionism. Instead, he was willing to rethink how the Transcendent might operate. Thus, he says about Schopenhauer: I felt sure that by "Will" he really meant God, the Creator, and that he was saying that God was blind. Since I knew from experience that God was not offended by any blasphemy, which on the contrary, he could even encourages it on the account that He wished to evoke not only man's bright and positive side but also his darkness and ungodliness, Schopenhauer's view did not distress me.
The Problem of Evil, which for so many people simply dehumanizes religion, and which Schopenhauer used to reject the value of the world, became a challenge for Jung in the psychoanalysis of God. The God of the Bible is indeed a personality, and seemingly not always the same one. God as a morally evolving personality is the extraordinary conception of Answer to Job. What Otto saw as the evolution of human moral consciousness, Jung turns right around on the basis of the principle that the human unconscious, expressed spontaneously in religious practice and literature, transcends mere human subjectivity. But the transcendent reality in the unconscious is different in kind from consciousness. As Jung said in Memories, Dreams, Reflections again: If the Creator were conscious of Himself, He would not need conscious creatures; nor is it probable that the extremely indirect methods of creation, which squander millions of years upon the development of countless species and creatures, are the outcome of purposeful intention. Natural history tells us of a haphazard and casual transformation of species over hundreds of millions of years of devouring and being devoured. The biological and political history of man is an elaborate repetition of the same thing. But the history of the mind offers a different picture. Here the miracle of reflecting consciousness intervenes - the second cosmogony [ed. note: what Teilhard de Chardin called the origin of the "oosphere," the layer of "mind"]. The importance of consciousness is so great that one cannot help suspecting the element of meaning to be concealed somewhere within all the monstrous, apparently senseless biological turmoil, and that the road to its manifestation was ultimately found on the level of warm-blooded vertebrates possessed of a differentiated brain - found as if by chance, unintended and unforeseen, and yet somehow sensed, felt and groped for out of some dark urge.
In other words, a "meaningful coincidence." Jung also says, As far as we can discern, the sole purpose of human existence is to kindle a light in the darkness of mere being. It may even be assumed that just as the unconscious affects us, so the increase in our consciousness affects the unconscious.
However, Jung has missed something there. If consciousness is "the light in the darkness of mere being," consciousness alone cannot be the "sole purpose of human existence," since consciousness as such could appear as just a place of "mere being" and so would easily become an empty, absurd, and meaningless Existentialist existence. Instead, consciousness allows for the meaningful instantiation of existence, both through Jung's process of Individuation, by which the Archetypes are given unique expression in a specific human life, and from the historic process that Jung examines in Answer to Job, by which interaction with the unconscious alters in turn the Archetypes that come to be instantiated. While Otto could understand Job's reaction to God, as the incomprehensible Numen, Jung thinks of God's reaction to Job, as an innocent and righteous man jerked around by God's unconsciousness. Jung's idea that the Incarnation then is the means by which God redeems Himself from His morally false position in Job is an extraordinary reversal (I hesitate to say "deconstruction") of the consciously expressed dogma that the Incarnation is to redeem humanity.
It is not too difficult to see this turn in other religions. The compassion of the Buddhas in Mahâyâna Buddhism, especially when the Buddha Shakyamuni comes to be seen as the expression of a cosmic and eternal Dharma Body, is a hand of salvation stretched out from the Transcendent, without, however, the complication that the Buddha is ever thought responsible for the nature of the world and its evils as their Creator. That complication, however, does occur with Hindu views of the divine Incarnations of Vishnu. Closer to a Jungian synthesis, on the other hand, is the Bahá'à theory that divine contact is though "Manifestations," which are neither wholly human nor wholly divine: merely human in relation to God, but entirely divine in relation to other humans. Such a theory must appear Christianizing in comparison to Islam, but it avoids the uniqueness of Christ as the only Incarnation in Christianity itself. This is conformable to the Jungian proposition that the unconscious is both a side of the human mind and a door into the Transcendent. When that door opens, the expression of the Transcendent is then conditioned by the person through which it is expressed, possessing that person, but it is also genuinely Transcendent and reflecting the ongoing interaction that the person historically embodies. The possible "mere being" even of consciousness then becomes the place of meaning and value.
Whether "psychoanalysis” as practised by Freud or Jung is to be taken seriously and no less than questions asked; however both men will survive as philosophers long after their claims to science or medicine may be discounted. Jung's Kantianism enables him to avoid the materialism and reductionism of Freud ("all of the civilization is a substitute for incest") and, with a great breadth of learning, employs principles from Kant, Schopenhauer, and Otto that are easily conformable to the Kant-Friesian tradition. The Answer to Job, indeed, represents a considerable advance beyond Otto, into the real paradoxes that are the only way we can conceive transcendent reality.
In the state of Cosmic Consciousness has an individual developed a keen awareness of his own mental states and activities and that of others around him or her. This individual is aware of a very distinct "I" personality that empowers the individual with a powerful expression of the "I am" that is not swayed or moved by the external impressions of the trifling mental states of others. This individual stands on a "rock solid" foundation that is not easily understood by the common mind. Cosmic Consciousness is void of the "superficial" ego.
The existence of the conscious "I" and the "Subconscious Mind" on the Mental Plane is a manifestation of the seventh Hermetic principle, the Principle of Gender. Every human, male and female, is composed of the Masculine and Feminine aspect of Mind on the Mental Plane. Each male has its female element, and each female has its male element of Mental Gender from which the creation of all thoughts proceed. The "I" being the masculine aspect of Mind, and the Subconscious Mind being the feminine. The Principle of Gender manifests itself as male and female in all species of Life and Being that makes the sexual reproduction and multiplication of the species possible on the Great Physical Plane. The phenomena of this principle can be found in all three great groups of life manifestations, as questionably answered to those that are duly respected thereof, that in the Spiritual, Mental, and Physical plane of Life and Being.
On the Physical Plane, its role is recognized as sexual reproduction, while on the higher planes it takes on higher, more subtler functions of Mental and Spiritual Gender. Its role is always in the direction of reproduction, generation and regeneration. The Masculine and Feminine principles are always present and active in all phases of phenomena and every plane of Life. An understanding in the manifesting power of this Principle, will give us a greater understanding of ourselves and an awareness of the enormous latent power awaiting to be tapped.
In the Spiritual developed individual, the person who becomes aware of, and recognizes the conscious "I," or "I am" within, will be able to exert its will upon the subconscious mind with definite causation and purpose. The recognition and awareness of the "I," will enable a person to expand his or her mind into regions of consciousness that is unthinkable to the societal conditioned thinking process of the world community.
True Spiritual, or Mental development, enables the sharpening of the five bodily senses, enhancing the richness of Life as our minds are allowed to expand into advanced Spiritual knowledge. Knowledge that will enable the proper use of the five wonderful bodily senses as they report to us the external world from which we derive information to store in the memory banks of the brain to create a knowledge base of experience. The greater the Conscious awareness, the more acute the bodily senses become. At the same time, the lesser the Conscious awareness (nonmaterial sixth sense), the minor acutely of the five bodily senses become and considerably of our external world would not even be acknowledged. This difference of mental states is most likely the cause of debate between religious and scientific circles.
The "I" Consciousness in each human is the true "Higher Self." The "Higher Self" of each human exists as a constant moving whirlpool of Cosmic Consciousness, or an eddy in the Infinite Spirit of "The all," which manifest’s LIFE in all of us and all living entities of the lower and higher planes. The "I" within all of us for being apart of the Mind but not separated exists in all of us and is the instrument of the conscious "I." It is Eternal and indestructible and mortality and Immortality is not an issue in existence. There is no force in existence capable of destroying the "I." This "I" or "Higher Self" is the SOUL of the Soul and is holographically connected to The all, giving the powerful "I" the Image of its Creator. All of us are created in the image of GOD without any exceptions or exclusions and none can escape its Omnipresent Infinite Living Mind. The all, of being the Ruler of all fate, or destiny, in all peoples, nations, governments, religious institutions, suns, worlds, galaxies, planes, dimensions, and Universes. All are subject to its Wills and Efforts, and is the Law that keeps all things in relationship to their Source. There is no "existence" outside of The all.
When the particular "I" is consciously recognized within ourselves, the "Will" of "I" is powerfully exerted upon the Subconscious Mind, giving the Subconscious Mind purpose and a sense of direction in Life. The Mind is the instrument by which the conscious "I" pries open the many deep, and hidden secrets of Nature.
To cause advancement, each individual would have to initiate the effort in learning the deep secrets of their nature, setting aside all the trifling efforts of self-condemnation, low self esteem, and hurts in their daily living that is caused by allowing the ignorant brainwashing of societal conditioning and self inflicted wounds. All the brainwashing, and imagined hurts that we experience in our lives are lessons to overcome these obstacles and to learn, and recognize the powerful "I."
Only the person who created the negative state of Mind can eliminate this by making a fundamental change in the way they think and what is held in their thoughts and to allow them the Spiritual education that is needed in for advancement. There is no red carpet treatment or royal road in accomplishing this. It takes a will, a desire, diligent effort, and perseverance in cultivating this knowledge. The resulting rewards of this attainment will far exceed the greatest worldly rewards known to humanity.
Most people fail to recognize this reality and they will unconsciously and painfully race through Life from cradle to grave and not even experience a momentary glimpse of this great Truth.
The "I," when recognized in a conscious and deliberate manner, will enable a person to accomplish things in Life that is limited only to his or her own imagination. The accomplishments of educators, scientists, engineers, and leaders, who make up the smaller percentage of the world population, have to a degree recognized this "I" within themselves, mostly in an unconscious manner, nevertheless, many have accomplished successful professional careers. They have accomplished a mental focus on a subject (or object), that escaped the ability of most people, giving them a sense of direction and a meaningful purpose in society. Every human is capable of accomplishing this, if they will only learn to focus and concentrate on one subject at a time.
When the will of "I" is utilized and exerted in an unrecognized and unconscious manner, it becomes misused and abused, bringing misery to the individual and others around him or her. Often, is this reality seen in the work place between people and where persons are in a position of authority, such as supervisors, managers, directors, etc., who bring misery to themselves and to their workers because of the powerful will of the unrecognized "I" or "I am." This aspect will cause a lack of harmony in an individual corporate, or company structure and at times bring chaos to the organization when enough of these types of individuals are employed in one place. Teamwork becomes a very labouring effort as competition between employees becomes its theme causing discontent and thus reducing the efficiency of a corporate environment. There is strength in number, either positive or negative. The realm of Spirit affects all levels of our society.
When the human Mind learns to become focussed on a single object or subject at a time, without wandering, excluding all other objects/subjects waiting in line, the Mind is capable of gathering previously unknown energy and information about a given subject or object. The entire world of that person seems to revolve in such a manner that it would bring them information from the unknown regions of the Mind. This is true meditation, to gather information about the unknown while being in a focussed meditative state of Mind. Each true meditation should bring a person information that will cause his or her Mind to expand with Knowledge, especially, when the focal point of concentration is that of Spirit. A person who learns to master this mental art will find that the proper books will manifest into their Life and bring to them the missing puzzles of Life. Books that will draw the attention of an individual on a given subject, and when the new knowledge is applied to the individual's Mind, it is allowed to expand further upon the subject by allowing the Mind to gather additional information and increasing the knowledge base, causing further advancement for others as well.
The mental art of concentration by employing the exertion of the will and creating desire upon a given subject or object is very rare because the lazy human mind is content with wandering twirlingly through Life. The untrained average human Mind is constantly rapidly wandering from one subject/object to another and is unable to focus on a single subject because of the constant carousel of external impressions of objects from the surrounding material world. The untrained mind is constantly jumping from one subject/object to another, like the jumping around of a wild monkey, never able to pause for a moment, to concentrate, and focalize long enough to allow the Mind to gather information about a given subject or object. This is what thinking is. To allow the Mind to gather information about the unknown. When this is disallowed, a person will wander aimlessly through Life and maintaining an ignorant state of Mind.
Wandering aimlessly through Life is a dangerous mental state to maintain because of the possible danger of other minds with stronger wills and efforts to manipulate the person who has not taken responsibility in the discipline and control of their own mind. A person having no control of their own responsibilities are more to wander of mind, having no control in Life's destiny because of the lack of focus and direction in Life. It can be compared with a rudderless ship that is constantly tossed by the rise and fall of the waves from the powerful ocean.
When the Mind becomes trained and learns to concentrate and focalize on a single object or subject at a time, that state of Mind will bring the individual Universal Knowledge and Wisdom. This is how genius is created by applying the mental art of concentration and focalizing on any worthwhile subject. The famous theories and hypothesis come into being such as Einstein's theory of relativity, man's ability to fly through the air, space travel, etc., by applying the mental art of concentration. It is an unbending mental aspect of the human mind as it continues to expand and gathers ever more information about all known and unknown subjects and objects, constantly causing change and advancement in Spirituality and technology. Unbiased, Spiritual Wisdom enables the proper use of technology and is the catalyst for its increasingly rapid advancement. It may be difficult, however, to conceive that Spirituality and technology go hand in hand, but are nonetheless, the lack of Spiritual Wisdom will dampen the infinite possibilities because of a limited, diminutive belief system.
Technology ends where the mortal barrier begins, then, it becomes a necessity to look into the realm of Spirit in order to continue human evolution. Without the continuous advancement of evolution, this civilization will become dissolved and perish off the face of the earth, like the many previous civilizations before us. The mortal barrier begins when science and technology will reach the limitation of the atomic and sub-atomic particles and a quantum leap into the realm of the Waveform (Spirit) becomes a necessity in order to continue upward progress
When a person learns to find a quiet moment in their lives to be able to become mentally focussed and entered on their profession, job, Spirituality, whatever the endeavour, they will find the answers and renewed energy to solve problems and create new knowledge and ideas.
When a person (no matter who) learns to focus and concentrate on Spirit, their Mind will gather from their Cosmic Consciousness, the deepest secrets of the Universe, as to how it is composed, by what means, and to what end. But, the enigma of the deepest inner secret Nature of The all, or God will always remain unknowable to us by reason of its Infinite stature to which no human qualities can, or should, ever be ascribed.
There is more on the subject of the powerful "I" consciousness the "I Am," the "Higher Self," which is, each one of us.
In what could turn out to be one of the most important discoveries in cognitive studies of our decade, it has been found that there are five million magnetite crystals per gram in the human brain. Interestingly, The meninges, (the membrane that envelops the brain), has twenty times that number. These ‘bio magnetite' crystals demonstrate two interesting features. The first is that their shapes do not occur in nature, suggesting that they were formed in the tissue, rather than being absorbed from outside. The other is that these crystals appear to be oriented so as to maximize their magnetic moment, which tends to give groups of these crystals the capacity to act as a system. The brain has also been found to emit very low intensity magnetic fields, a phenomenon that forms the basis of a whole diagnostic field, Magnetoencephalography.
Unfortunately for the present discussion, there is no way to ‘read' any signals that might be carried by the brain’s magnetic emissions at present. We expect that subtle enough means of detecting such signals will eventually appear, as there is compelling evidence that they do exist, and constitute a means whereby communication happens between various parts of the brain. This system, we speculate, is what makes the selection of which neural areas to recruit, so that States (of consciousness) can elicit the appropriate Phenomenological, behavioural, and affective responses.
While there have been many studies that have examined the effects of magnetic fields on human consciousness, none have yielded findings more germane to understanding the role of neuromagnetic signalling than the work of the Laurentian University Behavioural Neuroscience group. They have pursued a course of experiments that rely on stimulating the brain, especially the temporal lobes, with complex low intensity magnetic signals. It turns out that different signal’s produce different phenomena.
One example of such phenomenons is vestibular sensation, in which one's normal sense of balance is replaced by illusions of motion similar to the feelings of levitation reported in spiritual literature as well as the sensation of vertigo. Transient ‘visions', whose content includes motifs that also appear in near-death experiences and alien abduction scenarios have also appeared. Positive effectual parasthesias (electric-like buzzes in the body) have occurred. Another experiences that has been elicited neuromagnetically is bursts of emotion, most commonly of fear and joy. Although the content of these experiences can be quite striking, the way they present themselves is much more ordinary. It approximates the ‘twilight state' between waking and sleep called hypnogogia. This can produce brief, fleeting visions, feelings that the bed is moving, rocking, floating or sinking. Electric-buzz like somatic sensations and hearing an inner voice call one's name can also occur in hypnogogia. The range of experiences it can produce is quite broad. If all signals produced the same phenomena, then it would be difficult to conclude that these magnetic signals approximate the postulated endogenous neuromagnetic signals that create alterations in State. In fact, the former produces a wide variety of phenomena. One such signal makes some women apprehensive, but another doesn't. One signal creates such strong vestibular sensations that one can't stand up. Another doesn't.
The temporal lobes are the parts of the brain that mediate states of consciousness. EEG readouts from the temporal lobes are markedly different when a person is asleep, having a hallucinogenic seizure, or on LSD. Siezural disorders confined to the temporal lobes (complex partial seizures) have been characterized as impairments of consciousness. There was also a study done in which monkeys were given LSD after having various parts of their brains removed. The monkeys continued to ‘trip' no matter what part or parts of their brains were missing until both temporal lobes were taken out. In these cases, the substance did not seem to affect the monkeys at all. The conclusion seems unavoidable. In addition to all their other functions (aspects of memory, language, music, etc.), the temporal lobes mediate states of consciousness.
If exposing the temporal lobes to magnetic signals can induce alterations in States, then it seems reasonable to suppose that States find part of their neural basis in our postulated neuromagnetic signals, arising out of the temporal lobes.
Hallucinations are known to be the Phenomenological correlates of altered States. Alterations in state of consciousness leads, following input, and phenomena, whether hallucinatory or not, follows in response. We can offer two reasons for drawing this conclusion.
The first is one of the results obtained by a study of hallucinations caused by electrical stimulation deep in the brain. In this study, the content of the hallucinations was found to be related to the circumstances in which they occurred, so that the same stimulations could produce different hallucinations. The conclusion was that the stimulation induced altered states, and the states facilitated the hallucinations.
The second has to do with the relative speeds of the operant neural processes.
Neurochemical response times are limited by the time required for their transmission across the synaptic gap, .5 to 2msec.
By comparison, the propagation of action potentials is much faster. For example, an action potential can travel a full centimetre (a couple of orders of magnitude larger than a synaptic gap) in about 1.3 msec. The brain's electrical responses, therefore, happen orders of magnitude more quickly than do its chemical ones.
Magnetic signals are propagated with greater speeds than those of action potentials moving through neurons. Contemporary physics requires that magnetic signals be propagated at a significant fraction of the velocity of light, so that the entire brain could be exposed to a neuromagnetic signal in vanishingly small amounts of time.
It seems possible that neuromagnetic signals arise from structures that mediate our various sensory and cognitive modalities. These signals then recruit those functions (primarily in the limbic system) that adjust the changes in state. These temporal lobe signals, we speculate, then initiate signals to structures that mediate modalities that are enhanced or suppressed as the state changes.
The problem of defining the phrase ‘state of consciousness' has plagued the field of cognitive studies for some time. Without going into the history of studies in the area, we would like to outline a hypothesis concerning states of consciousness in which the management of states gives rise to the phenomenon of consciousness
There are theories that suggest that cognitive modalities (such as memory, affect, ideation and attention) may be seen as analogs to sensory modalities.
We hypothesize that the entire set of modalities, cognitive and sensory, may be heuristically compared with a sound mixing board. In this metaphor, all the various modalities are represented as vertical rheostats with enhanced functioning increasing towards the top, and suppressed function increasing toward the bottom. Further, the act of becoming conscious of phenomena in any given modality involves the adjustment of that modality's ‘rheostat'
Sensory input from any modality can alter one's state. The sight of a sexy person, the smell of fire, the unexpected sensation of movement against one's skin (there's a bug on me!), a sudden bitter taste experienced while eating ice cream, or the sound of one's child screaming in pain; all of these phenomena can induce alterations in State. Although the phrase ‘altered states' has come to be associated with dramatic, otherworldly experiences, alterations in state, as we will be using the phrase, refer primarily to those alterations that take us from one normal state to another.
Alterations in state can create changes within the various sensory and cognitive modalities. An increase in arousal following the sight of a predator will typically suppress the sense of smell (very few are able to stop and ‘smell the roses' while a jaguar is chasing them), suppressive introspection (nobody wants to know ‘who I really am?' Nonetheless, an anaconda breeds for wrapping itself around them, suppresses sexual arousal, and alters vision so that the centre of the visual field is better attended then one's peripheral vision allowing one to see the predator's movement better? The sight of a predator will also introduce a host of other changes, all of which reflect the State.
In the Hindu epic, the Mahabharata, there is a dialogue between the legendary warrior, Arjuna, and his archery teacher. Arjuna was told by his teacher to train his bow on a straw bird used as a target. Arjuna was asked to describe the bird. He answered ‘I can't'. ‘Why not?', Asked his teacher. ‘I can only see its eye', he answered. ‘Release your arrow', commanded the teacher. Arjuna did, and hit the target in the eye. ‘I'll make you the finest archer in the world', said his teacher.
In this story, attention to peripheral vision had ceased so completely that only the very centre of his visual field received any. Our model of states would be constrained to interpret Arjuna's (mythical) feat as a behaviour specific to a state. The unique combination of sensory enhancement, heightened attention, and sufficient suppression of emotion, ideation, and introspection that support such an act suggests specific settings for our metaphorical rheostats.
Changes in state make changes in sensory and cognitive modalities, and they in turn, trigger changes in state. We can reasonably conclude that there is a feedback mechanism whereby each modality is connected to the others.
States also create tendencies to behave in specific ways in specific circumstances, maximizing the adaptivity of behaviour in those circumstances; behaviour that tends to meet our needs and respond to threats to our ability to meet those needs.
Each circumstance adjusts each modality’s setting, tending to maximize that modality's contribution to adaptive behaviour in that circumstance. The mechanism may function by using both learned and inherited default settings for each circumstance and then repeating those settings in similar circumstances later on. Sadly, this often makes states maladaptive. Habitually to alteration in State, in response to threats from an abusive parent, for example, can make for self-defeating responses to stress in other circumstances, where theses same responses are no longer advantageous.
Because different States are going to be dominated by specific combinations of modalities, it makes sense that a possible strategy for aligning the rheostats (making alterations in state) is to move them in tandem, so that after a person associates the sound of a scream to the concept of a threat, that sound, with its unique auditory signature, will cause all the affected modalities (most likely most of them in most cases) to take the positions they had at the time the association was made.
hen we say changing states, we are referring to much more than the dramatic states created by LSD, isolation tanks, REM. sleep, etc. We are also including normal states of consciousness, which we can imagine as kindled ‘default settings' of our various modalities. When any one of these settings returns to one of its default settings, it will, we conjecture, tend to entrain all the other modalities to the settings they habitually take in that state.
To accomplish this, we must suggest that each modality be connected to every other one. A sight, a smell, a sound, or a tactile feeling can all inspire fear. Fear can motivate ideation. Ideation can inspire arousal. Changes in effect can initiate alterations in introspection. Introspection alters affect. State specific settings of individual modalities could initiate settings for other modalities.
Our main hypothesis here is that all these intermodal connections, as operating as a single system, have a single Phenomenological correlate. The phenomena of subjective awareness.
The structures associated with that modality then broadcasts are neuromagnetic signals to the temporal lobes, which then produces signals that then recruits various structures throughout the brain. Specifically, those structures whose associated modalities' values must be changed in order to accomplish the appropriate alteration in state. In the second section, we found the possibility that states are settings for the variable aspects of cognitive and sensory modalities. We also offered the suggestion that consciousness is the Phenomenological correlate of the feedback between the management of states on the one hand, and the various cognitive and sensory modalities, on the other. If all of these conclusions were to stand up to testing, we could conclude that the content of the brain's hypothesized endogenous magnetic signals might consist of a set of values for adjusting each sensory and cognitive rheostat. We might also conclude that neuromagnetic signalling is the context in which consciousness occurs.
The specific mechanism whereby subjectivity is generated is out of the reach of this work. Nevertheless, we can say that the fact that multiple modalities are experienced simultaneously, together with our model's implication that they are ‘reset,' all at once, with each alteration in state suggests that our postulated neuromagnetic signals may come in pairs, with the two signals running slightly out of condition with one another. In this way, neuromagnetic signals, like the two laser beams used to produce a hologram, might be able to store information in a similar way, as has already been explored by Karl Pibhram. The speed at which neuromagnetic signals continue to propagate, and together with their capacity to recruit/alter multiple modalities suggests that the underlying mechanism have been selected to make instant choices on which specific portions to recruit in order to facilitate the behaviours acted out of the State, and to do so quickly.
In this way, the onset time for the initiation of States is kept to a minimum, and with it, the times needed to make the initial, cognitive response to stimuli. When it comes to response to threats, or sighting prey, the evolutionary advantages are obvious.
Higher-order theories of consciousness try to explain the distinctive properties of consciousness in terms of some relation obtaining between the conscious state in question and a higher-order representation of some sort (either a higher-order experience of that state, or a higher-order thought or belief about it). The most challenging properties to explain are those involved in phenomenal consciousness - the sort of state that has a subjective dimension, which has ‘feel’, or which it is like something to undergo.
One of the advances made in recent years has been in distinguishing between different questions concerning consciousness. Not everyone agrees on quite which distinctions need to be drawn. But all are agreeing that we should distinguish creature consciousness from mental-state consciousness. It is one thing to say of an individual or organism that it is conscious (either in general or of something in particular). It is quite another thing to say of one of the mental states of a creature that it is conscious.
It is also agreed that within creature-consciousness itself we should distinguish between intransitive and transitive variants. To say of an organism that it is conscious, and finds of its own sorted simplicities (intransitive) is to say just that it is awake, as opposing to an ever vanquishing state of unconsciousness, only to premises the fact, that the unconscious is literally resting, not of an awakening state. There do not appear to be any deep philosophical difficulties lurking here (or at least, they are not difficulties specific to the topic of consciousness, as opposed to mentality in general). But to say of an organism that it is conscious of such-and-such (transitive) is normally to say at least that it is perceiving such-and-such, or aware of such-and-such. So we say of the mouse that it is conscious of the cat outside its hole, in explaining why it does not come out is, perhaps, to mean that it perceives the cat's presence. To provide an account of transitive creature-consciousness would thus be to attempt a theory of perception.
There is a choice to be made concerning transitive creature-consciousness, failure to notice which may be a potential source of confusion. For we have to decide whether the perceptual state in virtue of which an organism may be said to be transitively-conscious of something must itself be a conscious one (state-conscious). If we say ‘Yes’ then we will need to know more about the mouse than merely that it perceives the cat if we are to be assured that it is conscious of the cat - we will need to establish that its percept of the cat is itself conscious. If we say ‘No’, on the other hand, then the mouse's perception of the cat will be sufficient for the mouse to count as conscious of the cat, but we may have to say that although it is conscious of the cat, the mental state in virtue of which it is so conscious is not itself a conscious one! It may be best to by-pass any danger of confusion here by avoiding the language of transitive-creature-consciousness altogether. Nothing of importance would be lost to us by doing this. We can say simply that organism O observes or perceives x. We can then assert, explicitly, that if we wish, that its percept be or is not conscious.
Turning now to the notion of mental-state consciousness, the major distinction here is between phenomenal consciousness, on the one hand - which is a property of states that it is like something to be in, which have a distinctive ‘feel’ (Nagel, 1974) - and various functionally-definable forms of access consciousness, on the other. Most theorists believe that there are mental states - such as occurrent thoughts or judgments - which are access-conscious (in whatever is the correct functionally-definable sense), but which are not phenomenally conscious. In contrast, there is considerable dispute as to whether mental states can be phenomenally-conscious without also being conscious in the functionally-definable sense - and even more dispute about whether phenomenal consciousness can be reductively explained in functional and/or representational terms.
It seems plain that there is nothing deeply problematic about functionally-definable notions of mental-state consciousness, from a naturalistic perspective. For mental functions and mental representations are the staple fares of naturalistic accounts of the mind. But this leaves plenty of room for dispute about the form that the correct functional account should take. Some claim that for a state to be conscious in the relevant sense is for it to be poised to have an impact on the organism's decision-making processes, perhaps also with the additional requirement that those processes should be distinctively rational ones. Others think that the relevant requirement for access-consciousness is that the state should be suitably related to higher-order representations - experiences and/or beliefs - of that very state.
What is often thought to be naturalistically problematic, in contrast, is phenomenal consciousness. And what is really and deeply controversial is whether phenomenal consciousness can be explained in terms of some or other functionally-definable notion. Cognitive (or representational) theories maintain that it can. Higher-order cognitive theories maintain that phenomenal consciousness can be reductively explained in terms of representations (either experiences or beliefs) which are higher-order. Such theories concern us here.
Higher-order theories, like cognitive/representational theories in general, assume that the right level at which to seek an explanation of phenomenal consciousness is a cognitive one, providing an explanation in terms of some combination of causal role and intentional content. All such theories claim that phenomenal consciousness consists in a certain kind of intentional or representational content (analog or ‘fine-grained’ in comparison with any concepts we may possess) figuring in a certain distinctive position in the causal architecture of the mind. They must therefore maintain that these latter sorts of mental property do not already implicate or presuppose phenomenal consciousness. In fact, all cognitive accounts are united in rejecting the thesis that the very properties of mind or mentality already presuppose phenomenal consciousness, as proposed by Searle (1992, 1997) for example.
The major divides among representational theories of phenomenal consciousness in general, is between accounts that are provided in purely first-order terms and those that implicate higher-order representations of one sort or another (see below). These higher-order theorists will allow that first-order accounts - of the sort defended by Dretske (1995) and Tye (1995), for example - can already make some progress with the problem of consciousness. According to first-order views, phenomenal consciousness consists in analog or fine-grained contents that are available to the first-order processes that guide thought and action. So a phenomenally-conscious percept of red, for example, consisting in a state, with which the parallel contentual representations are red under which are betokened in such a way as to take food into thoughts about red, or into actions that are in one way or another guide by way of redness. Now, the point to note in favour of such an account is that it can explain the natural temptation to think that phenomenal consciousness is in some sense ineffable, or indescribable. This will be because such states have fine-grained contents that can slip through the mesh of any conceptual net. We can always distinguish many more shades of red than we have concepts for, or could describe in language (other than indexically -, e.g., ‘That shade’)
The main motivation behind higher-order theories of consciousness, in contrast, derives from the belief that all (or at least most) mental-state types admit of both conscious and non-conscious varieties. Almost everyone now accepts, for example, (post-Freud) that beliefs and desires can be activated non-consciously. (Think, here, of the way in which problems can apparently become resolved during sleep, or while one's attention is directed to other tasks. Notice, that appearance to non-conscious intentional states is now routine in cognitive science.) And then if we ask what makes the difference between a conscious and a non-conscious mental state, one natural answer is that consciously states are states we are aware of them but not as to their actualization as based upon its nature. And if awareness is thought to be a form of creature-consciousness, then this will translate into the view that conscious states are states of which the subject is aware, or states of which the subject is creature-conscious. That is to say, these are states that are the objects of some sort of higher-order representation - whether to some higher-order of perception or experience, or a higher-order of belief or thought.
One crucial question, then, is whether perceptual states as well as beliefs admit of both conscious and non-conscious varieties. Can there be, for example, such a thing as a non-conscious visual perceptual state? Higher-order theorists are united in thinking that there can. Armstrong (1968) uses the example of absent-minded driving to make the point. Most of us at some time have had the rather unnerving experience of ‘coming to’ after having been driving on ‘automatic pilot’ while our attention was directed elsewhere - perhaps having been day-dreaming or engaged in intense conversation with a passenger. We were apparently not consciously aware of any of the route we have recently taken, nor of any of the obstacles we avoided on the way. Yet we must surely have been seeing, or we would have crashed the car. Others have used the example of blindsight. This is a condition in which subjects have had a portion of their primary visual cortex destroyed, and apparently become blind in a region of their visual field as a result. But it has now been known for some time that if subjects are asked to guess at the properties of their ‘blind’ field (e.g., whether it contains a horizontal or vertical grating, or whether it contains an ‘X’ or an ‘O’), they prove remarkably accurate. Subjects can also reach out and grasp objects in their ‘blind’ field with something like 80% or more of normal accuracy, and can catch a ball thrown from their ‘blind’ side, all without conscious awareness.
More recently, a powerful case for the existence of non-conscious visual experience has been generated by the two-systems theory of vision proposed and defended by Milner and Goodale (1995). They review a wide variety of kinds of neurological and neuro-psychological evidence for the substantial independence of two distinct visual systems, instantiated in the temporal and parietal lobes respectively. They conclude that the parietal lobes provide a set of specialized semi-independent modules for the on-line visual control of action; Though the temporal lobes are primarily concerned with subsequent off-line functioning, such as visual learning and object recognition. And only the experiences generated by the temporal-lobe system are phenomenally conscious, on their account.
(Note that this is not the familiar distinction between what and where visual systems, but is rather a successor to it. For the temporal-lobe system is supposed to have access both to property information and to spatial information. Instead, it is a distinction between a combined what-where system located in the temporal lobes and a how-to or action-guiding system located in the parietal lobes.)
To get the flavour of Milner and Goodale's hypothesis, consider just one strand from the wealth of evidence they provide. This is a neurological syndrome called visual form agnosia, which results from damage localized to both temporal lobes, leaving primary visual cortex and the parietal lobes composed. (Visual form agnosia is normally caused by carbon monoxide poisoning, for reasons that are little understood.) Such patients cannot recognize objects or shapes, and may be capable of little conscious visual experience; still, their sensorimotor abilities remain largely intact
One particular patient has now been examined in considerable detail. While D.F. is severely agnosia, she is not completely lacking in conscious visual experience. Her capacities to perceive colours and textures are almost completely preserved. (Why just these sub-modules in her temporal cortex should have been spared is not known.) As a result, she can sometimes guess the identity of a presented object - recognizing a banana, say, from its yellow Collor and the distinctive texture of its surface. Nevertheless, she is unable to perceive the shape of the banana (whether straight or curved, say); Nor its orientation (upright or horizontal), nor of many of her sensorimotor abilities are close too normal - she would be able to reach out and grasp the banana, orienting her hand and wrist appropriately for its position and orientation, and using a normal and appropriate finger grip. Under experimental conditions it turns out that although D.F. is at chance in identifying the orientation of a broad line or letter box, she is almost normal when posting a letter through a similarly-shaped slot oriented at random angles. In the same way, although she is at chance when trying to choose as between the rectangular Forms of very different sizes, her reaching and grasping behaviours when asked to pick up such a Form are virtually indistinguishable from those of normal controls. It is very hard to make sense of this data without supposing that the sensorimotor perceptual system is functionally and anatomically distinct from the object-recognition/conscious system.
There is a powerful case, then, for thinking that there are non-conscious as well as conscious visual percepts. While the perceptions that ground your thoughts when you plan in relation to the perceived environment (‘I'll pick up that one’) may be conscious, and while you will continue to enjoy conscious perceptions of what you are doing while you act, the perceptual states that actually guide the details of your movements when you reach out and grab the object will not be conscious ones, if Milner and Goodale (1995) are correct
But what implication does this have for phenomenal consciousness? Must these non-conscious percepts also be lacking in phenomenal properties? Most people think so. While it may be possible to get oneself to believe that the perceptions of the absent-minded car driver can remain phenomenally conscious (perhaps lying outside of the focus of attention, or being instantly forgotten), it is very hard to believe that either blindsight percepts or D.F.'s sensorimotor perceptual states might be phenomenally conscious ones. For these perceptions are ones to which the subjects of those states are blind, and of which they cannot be aware. And the question, then, is what makes the relevant difference? What is it about a conscious perception that renders it phenomenal, which a blindsight perceptual state would correspondingly lack? Higher-order theorists are united in thinking that the relevant difference consists in the presence of something higher-order in the first case that is absent in the second. The core intuition is that a phenomenally conscious state will be a state of which the subject is aware.
What options does a first-order theorist have to resist this conclusion? One is to deny the data, it can be said that the non-conscious states in question lack the kind of fineness of grain and richness of content necessary to count as genuinely perceptual states. On this view, the contrast discussed above isn't really a difference between conscious and non-conscious perceptions, but rather between conscious perceptions, on the one hand, and non-conscious belief-like states, on the other. Another option is to accept the distinction between conscious and non-conscious perceptions, and then to explain that distinction in first-order terms. It might be said, for example, that conscious perceptions are those that are available to belief and thought, whereas non-conscious ones are those that are available to guide movement. A final option is to bite the bullet, and insist that blindsight and sensorimotor perceptual states are indeed phenomenally conscious while not being access-conscious. On this account, blindsight percepts are phenomenally conscious states to which the subjects of those states are blind. Higher-order theorists will argue, of course, that none of these alternatives is acceptable.
In general, then, higher-order theories of phenomenal consciousness claim the following: A phenomenally conscious mental state is a mental state (of a certain sort - see below) which either is, or is disposed to be, the object of a higher-order representation of a certain sort. Higher-order theorists will allow, of course, that mental states can be targets of higher-order representation without being phenomenally conscious. For example, a belief can give rise to a higher-order belief without thereby being phenomenally conscious. What is distinctive of phenomenal consciousness is that the states in question should be perceptual or quasi-perceptual ones (e.g., visual images as well as visual percepts). Moreover, most cognitive/representational theorists will maintain that these states must possess a certain kind of analog (fine-grained) or non-conceptual intentional content. What makes perceptual states, mental images, bodily sensations, and emotions phenomenally conscious, on this approach, is that they are conscious states with analog or non-conceptual contents. So putting these points together, we get the view that phenomenally conscious states are those states that possess fine-grained intentional contents of which the subject is aware, being the target or potential target of some sort of higher-order representation.
There are then two main dimensions along which higher-order theorists disagree among themselves. One relate to whether the higher-order states in question are belief-like or perception-like. That taking to the former option is higher-order thought theorists, and those taking the latter are higher-order experience or ‘inner-sense’ theorists. The other disagreement is internal to higher-order thought approaches, and concerns whether the relevant relation between the first-order state and the higher-order thought is one of availability or not. That is, the question is whether a state is conscious by virtue of being disposed to give rise to a higher-order thought, or rather by virtue of being the actual target of such a thought. These are the options that will now concern us.
According to this view, humans not only have first-order non-conceptual and/or analog perceptions of states of their environments and bodies, they also have second-order non-conceptual and/or analog perceptions of their first-order states of perception. Humans (and perhaps other animals) not only have sense-organs that scan the environment/body to produce fine-grained representations that can then serve to ground thoughts and action-planning, but they also have inner senses, charged with scanning the outputs of the first-order senses (i.e., perceptual experiences) to produce equally fine-grained, but higher-order, representations of those outputs (i.e., to produce higher-order experiences). A version of this view was first proposed by the British Empiricist philosopher John Locke (1690). In our own time it has been defended especially by Armstrong.
(A terminological point: this view is sometimes called a ‘higher-order experience (HOE) theory’ of phenomenal consciousness; But the term ‘inner-sense theory’ is more accurate. For as we will see in section 5, there are versions of a higher-order thought (HOT) approaches that also implicate higher-order perceptions, but without needing to appeal to any organs of inner sense.
(Another terminological point: ‘Inner-sense theory’ should more strictly be called ‘higher-order-sense theory’, since we of course have senses that are physically ‘inner’, such as pain-perception and internal touch-perception, which are not intended to fall under its scope. For these are first-order senses on a par with vision and hearing, differing only in that their purpose is to detect properties of the body rather than of the external world. According to the sort of higher-order theory under discussion in this section, these senses, too, determine what needs have their outputs scanned to produce higher-order analog contents in order for them to become phenomenally conscious. In what follows, however, the term ‘inner sense’ will be used to mean, more strictly, ‘higher-order sense’, since this terminology is now pretty firmly established.)
A phenomenally conscious mental state is a state with analog/non-conceptual intentional content, which is in turn the target of a higher-order analog/non-conceptual intentional state, via the operations of a faculty of ‘inner sense’.
On this account, the difference between a phenomenally conscious percept of red and the sort of non-conscious percepts of red that guide the guesses of a blindsighter and the activity of sensorimotor system, is as follows. The former is scanned by our inner senses to produce a higher-order analog state with the content experience of red or seems red, whereas the latter states are not - they remain merely first-order states with the analog content red. In so remaining, they lack any dimension of seeming or subjectivity. According to inner-sense theory, it is our higher-order experiential themes produced by the operations of our inner-senses which make some mental states with analog contents, but not others, available to their subjects. And these same higher-order contents constitute the subjective dimension or ‘feel’ of the former set of states, thus rendering them phenomenally conscious.
One of the main advantages of inner-sense theory is that it can explain how it is possible for us to acquire purely recognisable concepts of experience. For if we possess higher-order perceptual contents, then it should be possible for us to learn to recognize the occurrence of our own perceptual states immediately - or ‘straight off’ - grounded in those higher-order analog contents. And this should be possible without those recognizable concepts thereby having any conceptual connections with our beliefs about the nature or content of the states recognized, nor with any of our surrounding mental concepts. This is then how inner-sense theory will claim to explain the familiar philosophical thought-experiments concerning one's own experiences, which are supposed to cause such problems for physicalist/naturalistic accounts of the mind.
For example, I can think, ‘This type of experience [as of red] might have occurred in me, or might normally occur in others, in the absence of any of its actual causes and effects.’ So on any view of intentional content that sees content as tied to normal causes (i.e., to information carried) and/or to normal effects (i.e., teleological or an inferential role), this type of experience might occur without representing red. In the same sort of way, I will be able to think, ‘This type of experience [pain] might have occurred in me, or might occur in others, in the absence of any of the usual causes and effects of pains. There could be someone in whom these experiences occur but who isn't bothered by them, and where those experiences are never caused by tissue damage or other forms of a bodily insult. And conversely, there could be someone who behaves and acts just as I do when in pain, and in response to the same physical causes, but who is never subject to this type of experience.’ If we possess purely recognitional concepts of experience, grounded in higher-order percepts of those experiences, then the thinkability of such thoughts is both readily explicable, and apparently unthreatening to a naturalistic approach to the mind.
Inner-sense theory does face a number of difficulties, however. If inner-sense theory were true, then how is it that there is no phenomenology distinctive of inner sense, in the way that there is a phenomenology associated with each outer sense? Since each of the outer senses gives rise to a distinctive set of Phenomenological properties, you might expect that if there were such a thing as inner sense, then there would also be a phenomenology distinctive of its operation. But there doesn't appear to be any.
This point turns on the so-called ‘transparency’ of our perceptual experience (Harman, 1990). Concentrate as hard as you like on your ‘outer’ (first-order) experiences - you will not find any further Phenomenological properties arising out of the attention you pay to them, beyond those already belonging to the contents of the experiences themselves. Paying close attention to your experience of the Collor of the red rose, for example, just produces attention to the redness - a property of the rose. But put like this, however, the objection just seems to beg the question in favour of first-order theories of phenomenal consciousness. It assumes that first-order - ‘outer’ - perceptions already have a phenomenology independently of their targeting by inner sense. But this is just what an inner-sense theorist will deny. And then in order to explain the absence of any kind of higher-order phenomenology, an inner-sense theorist only needs to maintain that our higher-order experiences are never themselves targeted by an inner-sense-organ that might produce third-order analog representations of them in turn.
Another objection to inner-sense theory is as follows if there really were an organ of inner sense, then it ought to be possible for it to malfunction, just as our first-order senses sometimes do. And in that case, it ought to be possible for someone to have a first-order percept with the analog content red causing a higher-order percept with the analog content seems-orange. Someone in this situation would be disposed to judge, ‘It is rouge red, but, till, it immediately stands as non-inferential (i.e., not influenced by beliefs about the object's normal Collor or their own physical state). But at the same time they would be disposed to judge, ‘It seems orange’. Not only does this sort of thing never apparently occur, but the idea that it might do so conflicts with a powerful intuition. This is that our awareness of our own experiences is immediate, in such a way that to believe that you are undergoing an experience of a certain sort is to be undergoing an experience of that sort. But if inner-sense theory is correct, then it ought to be possible for someone to believe that they are in a state of seeming-orange when they are actually in a state of seeming-red.
A different sort of objection to inner-sense theory is developed by Carruthers (2000). It starts from the fact that the internal monitors postulated by such theories would need to have considerable computational complexity in order to generate the requisite higher-order experiences. In order to perceive an experience, the organism would need to have mechanisms to generate a set of internal representations with an analog or non-conceptual content representing the content of that experience, in all its richness and fine-grained detail. And notice that any inner scanner would have to be a physical device (just as the visual system of itself is) which depends upon the detection of those physical events in the brain that is the output of the various sensory systems (just as the visual system is a physical device that depends upon detection of physical properties of surfaces via the reflection of light). For it is hard to see how any inner scanner could detect the presence of an experience as experience. Rather, it would have to detect the physical realizations of experiences in the brain, and construct the requisite higher-order representation of the experiences that those physical events realize, on the basis of that physical-information input. This makes is seem inevitable that the scanning device that supposedly generates higher-order experiences of our first-order visual experience would have to be almost as sophisticated and complex as the visual system itself
Now the problem that arises here is this. Given this complexity in the operations of our organs of inner sense, there had better be some plausible story to tell about the evolutionary pressures that led to their construction. For natural selection is the only theory that can explain the existence of organized functional complexity in nature. But there would seem to be no such stories on the market. The most plausible suggestion is that inner-sense might have evolved to subserve our capacity to think about the mental states of conspecific, thus enabling us to predict their actions and manipulate their responses. (This is the so-called ‘Machiavellian hypothesis’ to explain the evolution of intelligence in the great-ape lineage. But this suggestion presupposes that the organism must already have some capacity for higher-order thought, since such thoughts in which an inner sense is supposed to subserve. And yet, some higher-order thought theories can claim all of the advantages of inner-sense theory as an explanation of phenomenal consciousness, but without the need to postulate any ‘inner scanners’. At any rate, the ‘computational complexity objection’ to inner-sense theories remains as a challenge to be answered.
Non-dispositionalist higher-order thought (HOT) theory is a proposal about the nature of state-consciousness in general, of which phenomenal consciousness is but one species. Its main proponent has been Rosenthal. The proposal is this: a conscious mental state M, of mine, is a state that is actually causing an activated belief (generally a non-conscious one) that I have M, and causing it non-inferentially. (The qualification concerning non-inferential causation is included to avoid one having to say that my non-conscious motives become conscious when I learn of them under psychoanalysis, or that my jealousy is conscious when I learn of it by interpreting my own behaviour.) An account of phenomenal consciousness can then be generated by stipulating that the mental state M should have an analog content in order to count as an experience, and that when M is an experience (or a mental image, bodily sensation, or emotion), it will be phenomenally conscious when (and only when) suitably targeted.
A phenomenally conscious mental state is a state with analog/non-conceptual intentional content, which is the object of a higher-order thought, and which causes that thought non-inferentially.
This account avoids some of the difficulties inherent in inner-sense theory, while retaining the latter's ability to explain the distinction between conscious and non-conscious perceptions. (Conscious perceptions will be analog states that are targeted by a higher-order thought, whereas perceptions such as those involved in blindsight will be non-conscious by virtue of not being so targeted.) In particular, it is easy to see a function for higher-order thoughts, in general, and to tell a story about their likely evolution. A capacity to entertain higher-order thoughts about experiences would enable a creature to negotiate the is and seems distinction, perhaps learning not to trust its own experiences in certain circumstances, and to induce appearances in others, by deceit. And a capacity to entertain higher-order thoughts about thoughts (beliefs and desires) would enable a creature to reflect on, and to alter, its own beliefs and patterns of reasoning, as well as to predict and manipulate the thoughts and behaviours of others. Indeed, it can plausibly be claimed that it is our capacity to target higher-order thoughts on our own mental state in which underlies our status as rational agents. One well-known objection to this sort of higher-order thought theory is due to Dretske (1993). We are asked to imagine a case in which we carefully examine two line-drawings, say (or in Dretske's example, two patterns of differently-sized spots). These drawings are similar in almost all respects, but differ in just one aspect - in Dretske's example, one of the pictures contains a black spot that the other lacks. It is surely plausible that, in the course of examining these two pictures, one will have enjoyed a conscious visual experience of the respect in which they differ -, e.g., of the offending spot. But, as is familiar, one can be in this position while not knowing that the two pictures are different, or in what way they are different. In which case, since one can have a conscious experience (e.g., of the spot) without being aware that one is having it, consciousness cannot require higher-order awareness.
Replies to this objection have been made by Seager (1994) and by Byrne (1997). They point out that it is one thing to have a conscious experience of the aspect that differentiates the two pictures, and quite another to experience consciously that the two pictures are differentiated by that aspect. That is, seeing the extra spot in one picture needn't mean seeing that this is the difference between the two pictures. So while scanning the two pictures one will enjoy conscious experience of the extra spot. A higher-order thought theorist will say that this means undergoing a percept with the content spot here which forms the target of a higher-order belief that one is undergoing a perception with that content. But this can perfectly well be true without undergoing a percept with the content spot here in this picture but absent here in that one. And it can also be true without forming any higher-order belief to the effect that one is undergoing a perception with the content spot here when looking at a given picture but not when looking at the other. In which case the purported counter-example isn't really a counter-example.
A different sort of problem with the Non-dispositionalist version of higher-order thought theory relates to the huge number of beliefs that would have to be caused by any given phenomenally conscious experience. (This is the analogue of the ‘computational complexity’ objection to inner-sense theory, Consider just how rich and detailed a conscious experience can be. It would seem that there can be an immense amount of which we can be consciously aware at any-one time. Imagine looking down on a city from a window high up in a tower-Form, for example. In such a case you can have phenomenally conscious percepts of a complex distribution of trees, roads, and buildings, colours on the ground and in the sky above, moving cars and pedestrians, . . . and so on. And you can - it seems - be conscious of all of this simultaneously. According to Non-dispositionalist higher-order thought theory, then, you would need to have a distinct activated higher-order belief for each distinct aspect of your experience is that, of just a few such beliefs with immensely complex contents. By contrast, the objection is the same, for which it seems implausible that all of this higher-order activity should be taking place, even if non-consciously, in every time someone is the subject of a complex conscious experience. For what would be the point? And think of the amount of cognitive space that these beliefs would take up,
This objection to Non-dispositionalist forms of higher-order thought theory is considered at some length in Carruthers (2000), where a variety of possible replies are discussed and evaluated. Perhaps the most plausible and challenging such replies would be to deny the main premise lying behind the objection, concerning the rich and integrated nature of phenomenally conscious experience. Rather, the theory could align itself with Dennett's (1991) conception of consciousness as highly fragmented, with multiple streams of perceptual content being processed in parallel in different regions of the brain, and with no stage at which all of these contents are routinely integrated into a phenomenally conscious perceptual manifold. Rather, contents become conscious on a piecemeal basis, as a result of internal or external probing that gives rise to a higher-order belief about the content in question. (Dennett himself sees this process as essentially linguistic, with both probes and higher-order thoughts being formulated in natural language. This variant of the view, although important in its own right, is not relevant to our present concerns.) This serves to convey to us the mere illusion of riches, because wherever we direct our attention, there we find a conscious perceptual content. It is doubtful whether this sort of ‘fragmental’ account can really explain the phenomenology of our experience, however. For it still faces the objection that the objects of attention can be immensely rich and varied at any given moment, hence requiring there to be an equally rich and varied repertoire of higher-order thoughts tokened at the same time. Think of immersing yourself in the colours and textures of a Van Gogh painting, for example, or the scene as your look out at your garden - it would seem that one can be phenomenally conscious of a highly complex set of properties, which one could not even begin to describe or conceptualize in any detail. However, since the issues here are large and controversial, it cannot yet be concluded that Non-dispositionalist forms of higher-order thought theory have been decisively refuted.
According to all forms of dispositionalist higher-order thought theory, the conscious status of an experience consists in its availability to higher-order thought (Dennett, 1978). As with the Non-dispositionalist version of the theory, in its simplest form we have here a quite general proposal concerning the conscious status of any type of occurrent mental state, which becomes an account of phenomenal consciousness when the states in question are experiences (or images, emotions, etc.) with analog content. The proposal is this: a conscious mental event M, of mine, is one that is disposed to cause an activated belief (generally a non-conscious one) that I have M, and to cause it non-inferentially.
A phenomenally conscious mental state is a state with analog/non-conceptual intentional content, which is held in a special-purpose short-term memory store in such a way as to be available to cause (non-inferentially) higher-order thoughts about any of the contents of that store.
In contrast with the Non-dispositionalist form of theory, the higher-order thoughts that render a percept conscious are not necessarily actual, but potential, on this account. So the objection now disappears, that an unbelievable amount of cognitive space would have to be taken up with every conscious experience. (There need not actually be any higher-order thought occurring, in order for a given perceptual state to count as phenomenally conscious, on this view.) So we can retain our belief in the rich and integrated nature of phenomenally conscious experience - we just have to suppose that all of the contents in question are simultaneously available to higher-order thought. Nor will there be any problem in explaining why our faculty of higher-order thought should have evolved, nor why it should have access to perceptual contents in the first place - this can be the standard sort of story in terms of Machiavellian intelligence.
It might be wondered how their mere availability to higher-order thoughts could confer on our perceptual states the positive properties distinctive of phenomenal consciousness - that is, of states having a subjective dimension, or a distinctive subjective feel. The answer may lie in the theory of content. Suppose that one agrees with Millikan (1984) that the representational content of a state depends, in part, upon the powers of the systems that consume that state. That is, suppose one thinks that what a state represents will depend, in part, on the kinds of inferences that the cognitive system is prepared to make in the presence of that state, or on the kinds of behavioural control that it can exert. In which case the presence of first-order perceptual representations to a consumer-system that can deploy a ‘theory of mind’, and which is capable of recognitizable applications of theoretically-embedded concepts of experience, may be sufficient to render those representations at the same time as higher-order ones. This would be what confers on our phenomenally conscious experiences the dimension of subjectivity. Each experience would at the same time (while also representing some state of the world, or of our own bodies) be a representation that we are undergoing just such an experience, by virtue of the powers of the ‘theory of mind’ consumer-system. Each percept of green, for example, would at one and the same time be an analog representation of green and an analog representation of seems green or experience of green. In fact, the attachment of a ‘theory of mind’ faculty to our perceptual systems may completely transform the contents of the latter's outputs.
This account might seem to achieve all of the benefits of inner-sense theory, but without the associated costs. (Some potential drawbacks will be noted in a moment.) In particular, we can endorse the claim that phenomenal consciousness consists in a set of higher-order perceptions. This enables us to explain, not only the difference between conscious and non-conscious perception, but also how analog states come to acquire a subjective dimension or ‘feel’. And we can also explain how it can be possible for us to acquire some purely recognitizable concepts of experience (thus explaining the standard philosophical thought-experiments). But we don't have to appeal to the existence of any ‘inner scanners’ or organs of inner sense (together with their associated problems) in order to do this. Moreover, it should also be obvious why there can be no question of our higher-order contents getting out of line with their first-order counterparts, in such a way that one might be disposed to make recognitizable judgments of red and seems orange at the same time. This is because the content of the higher-order experience is parasitic on the content of the first-order one, being formed from it by virtue of the latter's availability to a ‘theory of mind’ system.
On the downside, for which the account is not neutral on questions of semantic theory. On the contrary, it requires us to reject any form of pure input-semantics, in favour of some sort of consumer-semantics. We cannot then accept that intentional content reduces to informational content, nor that it can be explicated purely in terms of causal covariance relations to the environment. So anyone who finds such views attractive will think that the account is a hard one to swallow.
What will no doubt be seen by most people as the biggest difficulty with dispositionalist higher-order thought theory, however, is that it may have to deny phenomenal consciousness to most species of non-human animals. This objection will be discussed, among others, in the section following, since it can arguably also be raised against any form of higher-order theory.
There has been the whole host of objections raised against higher-order theories of phenomenal consciousness. Unfortunately, many of these objections, although perhaps intended as objections to higher-order theories as such, are often framed in terms of one or another particular version of such a theory. One general moral to be taken away from the present discussion should then be this: the different versions of a higher-order theory of phenomenal consciousness need to be kept distinct from one another, and critics should take care to state which version of the approach is under attack, or to frame objections that turn merely on the higher-order character of all of these approaches.
One generic objection is that higher-order theory, when combined with plausible empirical claims about the representational powers of non-human animals, will conflict with our commonsense intuition that such animals enjoy phenomenally conscious experience. This objection can be pressed most forcefully against higher-order thought theories, of either variety; However it is also faced by inner-sense theory (depending on what account can be offered of the evolutionary function of organs of inner sense). Since there is considerable dispute as to whether even chimpanzees have the kind of sophisticated ‘theory of mind’ which would enable them to entertain thoughts about experiential states as such (Byrne and Whiten, 1988, 1998; Povinelli, 2000), it seems most implausible that many other species of a mammal (let alone reptiles, birds and fish) would qualify as phenomenally conscious, on these accounts. Yet the intuition that such creatures enjoy phenomenally conscious experiences is a powerful and deep-seated one, for many people.
The grounds for this commonsense intuition can be challenged, however. (How, after all, are we supposed to know whether it is like something to be a bat?) And that intuition can perhaps be explained away as a mere by-product of imaginative identification with the animal. (Since our images of their experiences are phenomenally conscious, that the experience’s imageable is similarly conscious. But there is no doubt that one crux of resistance to higher-order theories will lie here, for many people.
Another generic objection is that higher-order approaches cannot really explain the distinctive properties of phenomenal consciousness. Whereas the argument from animals is that higher-order representations aren't necessary for phenomenal consciousness, the argument here is that such representations aren't sufficient. It is claimed, for example, that we can easily conceive of creatures who enjoy the postulated kinds of higher-order representation, related in the right sort of way to their first-order perceptual states, but where those creatures are wholly lacking in phenomenal consciousness.
In response to this objection, higher-order theorists will join forces with first-order theorists and others in claiming that these objectors pitch the standards for explaining phenomenal consciousness too high. We will insist that a reductive explanation of something - and of phenomenal consciousness in particular - don’t have to be such that we cannot conceive of the explanandum (that which is being explained) in the absence of the explanans (that which does the explaining). Rather, we just need to have good reason to think that the explained properties are constituted by the explaining ones, in such a way that nothing else needed to be added to the world once the explaining properties were present, in order for the world to contain the target phenomenon. But this is disputed territory. And it is on this ground that the battle for phenomenal consciousness may ultimately be won or lost
While orthodox medical research adheres to a linear, deterministic physical model, alternative therapist typically theorize upon that which is indeterminately nonphysical and nonlinear relationships are significant to outcome and patient satisfaction. The concept of nonlocal reality as nuocontinuum helps resolve the differences in therapeutic approach, and lets us frame a worldview that recognizes the great value of both reductive science and holistic integration. It helps distinguish the levels of description appropriate to the discussion of each, and helps in examining the relationships among consciousness, nonlocal reality, and healing.
Most recently addressed is to some informal discussion for which the problems of evaluating alternative therapies, but Dossey highlighted the stark philosophic division between orthodox and alternative health care models. While orthodox medical research adheres to a linear, deterministic physical model, alternative therapist typically postulates that indeterminate nonphysical and nonlinear relationships are significant to outcome and patient satisfaction. As Dossey summarizes that position, "Everything that counts cannot be counted."
The problems, of course, go beyond the research issues. The respective models bring different attitudes and approaches to the therapeutic encounter. Further, their different philosophic languages limit discussions among practitioners. Rapproachment becomes all the more unlikely when each camp considers the other, "wrong." It is believed to be helpful if we were to visualize the conflict as deriving from different frames of reference. Our collective task then becomes the finding of a common frame of reference a "cosmos in common," to echo Heraclitus sufficiently broad and deep to encompass both linear and nonlinear, local and nonlocal therapeutic points of view.
If we are to remain true to science, we must integrate the data that science provides us, and be willing to follow where the process leads. It is increasingly apparent that physics requires us to acknowledge meta considerations, that is, considerations that lie above and beyond physics. Those of us biomedical practitioners who base our work on physics cannot disparage as "merely metaphysics" a meta physics to which physics itself points.
As a point of departure, I would like to "frame" in general outlines a worldview that recognizes the great value of both reductive science and holistic integration, and which helps distinguish the levels of description appropriate to the discussion of each. In doing so, I will suggest a new and unweighted ecumenical term for discussing the relationships among consciousness, nonlocal reality, and healing.
The cosmos is the general descriptive term for all-that-is, which we have come to understand as an organic system of interrelated nested subsystems. Yet its most ancient representation in art is a circle. In our ordinary positivist view of things conditioned by science, the term denotes only the material nature of the universe, governed by the laws of physics. In the ordinary local cause-effect world, time-distance relationships apply, and the speed limit is that of light. Actions are mediated through a field, and forces are dissipated over distance.
However, Bell's Theorem in quantum physics establishes that "underneath" ordinary space-time phenomena there lies a deep nonlocal reality in which none of these limitations applies. To diagram cosmos one must find an appropriate way to divide the one circle. We might add an inner concentric circle, but the cosmos, as the term is currently used, would identify only the outer material "shell" of our experience of physical things. We have no agreed technical term for that which is "more" than matter, or beyond or outside it, or inside it. Syche has scientific validity as a psychological term. It denotes an inner personal dimension representing that aspect of experience that is normally unconscious to us, but which nevertheless influences individual human behaviour. However, in ordinary usage, the term psyche (soul, spirits) has no meaning apart from the individual human personality. To speak of the soul or spirit of matter (one hardly dare do so publicly) does not compute. Yet, now physics says there is a nonlocal more to the matter-work of the cosmos, and that domain is somehow related to the existence of consciousness.
But there needs to be still another inner concentric circle, or at least a centre-point. Cosmologists are beginning to speak more openly about a purposeful cosmos. For example, Hawking has asked, "Why does the universe go to the integral of the bother of existing?" If science is to ask "Why" as Hawking does, it must seek the "meaning" of matter. But Meaning ordinarily has no significance in science. To speak of meaning is to speak of significance or order beyond superficial appearances. To speak of meaning in relation to the cosmos is to speak of metaphysics, the realm of religion and philosophy.
Yet, such meaning is implicit in the anthropic principle of physics, and in the strange attractors by which order emerges from chaotic chemical and nonlinear mathematical systems. Though such meaning is an idea new to modern science, religion and philosophy have variously described it as logos, to Way, and Word. In that of residing in "lure" of an orienting change, as mentioned by Whitehead, and in the function of the radial energy of which Teilhard spoke.
Now, on scientific grounds alone, we must devise a "cosmorama" of at least three compartments, if it is to encompass the phenomena of the universe. Resolving and explaining these relationships may be quite complex; or it may be surprisingly simple. In any case, there are a number of questions to be answered, and a number of problems in physics and psychology that invite us to frame a unification theory.
One principal problems in quantum physics is the question of observer effect. What is the role of consciousness in resolving the uncertainties of actions at the quantum level? Before an observation, the question of whether a quantum event has occurred can be resolved only by calculating a probability. The unconscious reality of the event is that it is a mix of the probabilities that it has happened and that it has not. That "wave function" of probabilities is said to "collapse" only at the point of observation, that is, only in the interaction of unconsciousness with consciousness.
Schrödinger illustrated the problem by describing a thought experiment involving a cat in a sealed box: If the quantum event happened, the cat would be poisoned; if not, when the box was opened, the cat would be found alive. Until then, we could know the result only as a calculation of probabilities. Under the condition’s Schrödinger described, we may think of the cat's condition only mathematically: the cat is both dead and alive, with equal probability. Only by the interaction of event with observer is the "wave function collapsed."
If a tree falls in the forest when there is no one present to hear it, has there been a sound? That question can be resolved by adjusting the definition of sound. In the question of the quantum "event in the box" we are dealing with something much more fundamental. Can creation occur without an observer? Without consciousness? Or without at least the prospect of consciousness emerging from the act of creation? That may be the most basic question that begs resolving.
Another of our unification problems is the virtual particle phenomenon. Some particles appear unpredictably, exist for extremely short periods of time, then disappear. Why does a particle appear in the force field suddenly, without apparent cause? What distinguishes stable particles from the temporary ones? Something in the force field? Something related to the act of observation?
Another major concern of physics is the unification of the elemental physical forces. Study of the "several" forces has progressively merged them. Electricity and magnetism came to be understood as one force, not two. More recently, effects associated with the weak nuclear force were reconciled with electromagnetism, so that now we recognize one electroweak force. Further, there have been mathematical demonstrations that unify the electroweak and the strong nuclear force.
If it could be demonstrated that the "electronuclear" force and the force of gravity are one super force (as has been widely expected), energy effects at the largest and the smallest scales of the universe would be explained. That unification process has led to a theory of a multidimensional universe, in which there are at least seven "extra" dimensions that account for the forces and the conservation laws (symmetries) of physics. They are not extra dimensions of space-time, for which one could devise bizarre travel itineraries, but abstract mathematical dimensions that in some sense constitute the nonlocal (non-space time) reality within which cosmos resides.
However, the search for a unified theory has led to an apparent impasse, for theories of unification seem also to require a continuing proliferation of particles. A new messenger particle (or class of particles) called the Higgs boson, seems to be needed to explain how particles acquire mass, and to avoid having infinity terms (the result of a division by zero) crop up in the formulas that unify the forces. Leon Lederman, experimental physicist and Nobelist, calls it "The God Particle." He writes, "The Higgs field, the standard model, and our picture of how God made the universe depend on finding the Higgs boson."
Still, major questions remain. To some others, particle physics has seemed to reach its limit, theoretically as well as experimentally. Oxford physicist Roger Penrose has written: If there is to be a final theory, it could only be a scheme of a very different nature. Rather than being a physical theory in the ordinary sense, it would have to remain a principle, as a mathematical principle of whose implementation might have itself involve nonmechanical subtlety.
Perhaps the time has come for us to accept that cosmos has "infinity terms" after all.
Psychology is conventionally defined as the study of behaviour, but for our purposes, it must be returned to the meaning implied in the roots of the word: the study of soul and spirit. Of course, the most obvious phenomenon of psychology is the emergence of consciousness. In the light of the anthropic principle of physics, we now must ask, as a distinctively psychological question, what purpose for the cosmos does consciousness serve?
Another question: Jung has presented the evidence for an archetypal collective unconscious that, on the basis of current understandings, must certainly be inherited as the base-content of human nature. Archetypal genetics has yet to be defined. Symbol processing certainly does have its "local" physical aspect, in the function of the brain and the whole-body physiology that supports it. Nonetheless, that there is a nonlocal reality undergirding psyche is readily evident.
The reality of the dream experience is nonlocal, unconfined by rules of time and space and normal effect. Further, it is nonlocal in that the reality extends beyond the individual, consistently following patterns evident throughout the recorded history of dream and myth. The psyche functions as though the brain, or at least its mechanisms of consciousness, is "observer" for the dream "event in the box" of an unconscious nonlocal collective reality. The archetypal unconscious suggests that there be a psychological substrate from which consciousness and its content have emerged.
In the emergence of consciousness primally, and in the extension of consciousness in modern people through the dreaming process, the collective unconscious (self) seems to serve a nonlocal integrating function, yielding images that the conscious (ego) must differentiate from its "local" observations of the external space-time world. Thus, is consciousness extended.
In that process, however, the ego must self-reflectively also "keep in mind" that our perception of the external physical world is not the reality of the physical world, but an interpretation of it; Nor is the external phenomenal world the only reality. To keep our interpretations of the physical world "honest," we must subject observation to tests of consistency and reason, but the calculus of consciousness is the calculus of whole process, both differential and integral. Consciousness cannot be extended, but is diminished, when it denies the reality of the unconscious.
Jung has also pointed to certain meaningful associations between events in psyche and events in the physical world, but which are not related causally. He called such an association a synchronicity, which he defines as "an accusal connecting principle." These are simultaneous or closely associated conversions that not have connected physically, in any ordinary cause-effect way. However, they are connected meaningfully, that is, psychically. They may have very powerful impact on a person's psychic state and on the subsequent unfolding of personality. Jung studied them with Wolfgang Pauli, a quantum physicists in whose life such phenomena were overly frequent.
A synchronicity seems to suggest that a nonlocal psychological reality either communicate with or is identical to the nonlocal reality known in physics. Since it is inconceivable to have two nonlocal realities coexisting separately from one, another, we can confidently assert that there is indeed, only one nonlocal reality.
Another set of phenomena inviting consideration is that which includes group hysteria and mob action. A classic example is that of a high school band on a bus trip, on which all members get "food poisoning" simultaneously before a big game. After exhaustive epidemiological work, no evidence of infection or toxins is found, and the "cause" is attributed to significant amounts where stress and the power of suggestion lay. The mechanisms are entirely unconscious to the band members; it is as though their psyches have "communicated" in a way that makes them act together. Similarly, in mob action, though the members may be conscious of the anger that moves them, generally the event seems to be loaded with an unconscious dynamic within the group that prepares the way for the event itself.
Physicist Paul Davy has written that one of the basic problems is constructing an adequate definition of the dimensionality. The ordinary dictionary definition describes a dimension in terms of magnitude or direction (height, depth, width), and we ordinarily think of the dimensions as perpendicular to each other. But that works only for the familiar spatial dimensions and the actions of ordinary objects. Imagine compressing all three-dimensional space toward a single point; As it comes close to a point, the concept of being perpendicular loses all meaning. Another problem is that it does not really make sense to think of time (which is a dimension, too) as perpendicular to anything.
A dimension is one of the domains of action permitted to or on an object. By domain I mean something like a field of influence or action. Verticality is not a thing that acts on an object, but is rather than which permits and influences a movement in space, and which influences our description of the movement. For example, verticality is one particular aspect of abstract reality that determines the behaviour of an object. But the abstract is real! Take verticality away from three-dimensional space, and an object is permitted to move only in a way that we can analyse as a mix of horizontal and forward-backward motions. Take the horizontal away, and the object may move only along a straight line (one-dimensional space). "String" theories, which approach a "Grand Unification" of all of the physical forces, posit dimensions beyond the four of the space-time. There is no theoretical limit to the number of dimensions, for external to space-time there is no concept of "container" or limit.
Since all of the non-space time dimensions, by definition, are not extended in space or time, we must conceive of them as represented by points. Since they act together of o space-time, they must "intersect" or somehow communicate with the primal space-time point. For that reason (and because in the absence of space-time no point can be offset from another), we must imagine the dimensions as many points superimposed into one. Let's call it the SuperPaint. We may in fact imagine as many superimposed points (dimensions) as past and future experiments might require to explain the phenomena of creation.
The initial conditions of our space-time universe are defined in that one SuperPaint; the Big Bang represents the explosive expansion of four of those dimensions, space-time. The creation-energy (super force) responsible for that expansion is concentrated in and at the multidimensional SuperPaint. Yet we must also think of other changes at the SuperPaint, for as energy levels dissipate immediately after the Big Bang, the super force quickly "evolves" into the four physical forces conventionally known.
We have said that only the space-time dimensions are expanding, because the force dimensions ("contained" in the SuperPaint) are not spatial. By definition, we may not imagine non-space time points as extended in space. However, all points in expanding space-time must still "communicate" with the force dimensions (and the symmetry dimensions, but we are neglecting them for the moment). All points in space-time must intersect the force dimensions.
It is as if the force dimensions too have been expanded to the size of space-time, for they are acting on each particle of energy/matter in the universe. One might imagine that one point has been stretched as a featureless elastic sheet, a continuum in which the point is everywhere the same.
However, quantum theory deals with these forces as discrete waves/particles. For example, the force of gravity is communicated by gravitons; The strong nuclear force by gluons is the electromagnetic force by photons. If we conceive the stretched points of the dimensions as "sheets," the sheets must have waves in them. These "stretched sheets" which constitute the field in which energy interacts with particles to sustain (and indeed, to continue the creation of) the universe. As I have expressed it in a poem, it is the field "where the forces play pinball / with gravitons and gluons / and modulate / the all."
Let us imagine again that space-time (four dimensions) is compressed toward a point. It is futile to ask what is outside that small pellet of space-time, for the concept of "outside ness" has no meaning but within space-time. As the pellet becomes smaller still, it shrinks toward nothingness, for a point is an abstract concept of zero dimensions, not extended in space or time, and thus it cannot "contain" anything. At that point, nothing exists except the thinker who is trying to imagine nothingness.
If we could model thought as only an epiphenomenon of matter, reached at a certain degree of complexity, it has no fundamental reality of its own. In that case, our thought experiment to shrink the cosmos reaches a point at which thought is extinguished, and the experiment must stop, if it is to follow the "rules" that it is modelling. However, by accepting that thought might have a reality of its own, and by considering the problem from a whole-system perspective, we were able to continue the thought experiment to the point at which only the thought remains. The epiphenomenon idea is not an adequate model of reality, since we can indeed continue the experiment under the conditions outlined.
This "negative proof" is indirect, serving only to eliminate the epiphenomenon model. It does not prove that there is an independent and fundamental reality beyond space-time and matter; the experiments supporting Bell's Theorem do that. This line of thinking, however, does lead us to suggest that thought be a primary aspect of reality. It seems that the cosmos itself is saying with Descartes, "I think, therefore I am."
Because of this inescapable "relativistic" connection between cosmos and thought, I cannot imagine creation ex nihilo (from nothing), for the concept of nothing always collides with the existence of the one who is the thinker. Nothing has any meaning apart from something. The dimension of thinking is required to imagine a zero-dimensional space-time.
The epiphenomenon model posits that nothing is defined as the absence of matter. If that is so, thought is nothing; However, if it were nothing, I could not be thinking that thought, so thought must be of something. There can be no nothingness, for even if all that exists is reduced to nothingness, a dimension of reality remains. Reality requires at least one dimension in addition to space-time and that reality seems inseparable from the dimension of thought.
What is missing from our existing scheme of dimensions is a description of that dimension that we could not eliminate by playing the videotape of creation in reverse: that reality at the SuperPaint from which the dimension of thought cannot be separated. That leads to a rather extravagant and intuitive proposal, following Anaxagoras: Thought is the missing particle, the missing dimension.
Quantum physics already acknowledges the importance of consciousness as "observer." Consciousness is the substrate of thought. Thought is consciousness dimensionally extended, whether in time or some other dimension. Thought is process. Any unification of the laws of physics must necessarily take into account the thought/consciousness dimension, and thus must unify physics with psyche as well.
In his book. The self-aware Universe, Admit Goswami uses the term consciousness to mean transcendental consciousness, which forms (or is) the nonlocal reality. Other physicists seem to define the term of cautiously, and one often wonders whether a given text about observer effect is referring to ordinary individual awareness, or to some more general property of psyche.
It is useful to preserve the important distinction between consciousness and unconsciousness. Psychologically, ordinary human consciousness is the realm of ego and the cognitive functions called mind. Neurologically it refers to a patient's observed state of awareness. The clinical unconscious is the realm of psyche, with both personal and collective aspects. Perhaps a better language will come along in time. Until then, let me suggest an interim language for discussing, and perhaps a framework for someday testing, the relationship between matter and psyche. Its proposal is that there is a unit of psyche, which I designate the neon, from the Greek word nous, for mind. Nuons represent the dimensions of thought that exist in (at, as) the SuperPaint defining the initial conditions of the Big Bang. As the domain of the force dimensions, those Nuons must be imagined to expand as a field or continuum (the nuocontinuum) as the space-time continuum expands, a "stretched sheet" with "waves" which are also Nuons. The Nuons of the SuperPaint are extended in space-time in a way conceptually analogous to the action of the forces.
Yet Nuons must also be construed as the domain of the symmetries, such as the principle of conservation of energy, which are nonlocal. That is, they are everywhere in effect, without being constrained by the speed-limit of light. The nuocontinuum thus represents a multidimensional bridge between forces, symmetries, and space-time. Nuons collectively contain all potentialities, but the collective (nuocontinuum) is the unit, itself the symmetry that unifies the forces and symmetries. The Nuons is the "infinity particle" which solves the formulas.
Does the nuocontinuum represent a fractal (fractional dimensions) such as those that give the mathematical order to the "chaos" images? Does it provide the prime tone of which the symmetries and the forces are harmonics? Whether construed mathematically or poetically, the nuocontinuum contains the information necessary to create a universe, but a universe that is organically creating itself.
Human awareness, which occurs at a level of extraordinary complexity in the organization of space-time particles, would involve, not a "creation" of consciousness as an epiphenomenon, but a sensing of a quality that is already there, as the reality dimension of the cosmos. The observer effect at the quantum level (and the health of Schr”dinger's cat) is then to be understood as an interaction, not with a particle of concrete matter, but with the reality substrate from which matter arises.
If we construe the whole nuocontinuum (rather than the experimenter) to be the "observer" of the quantum event in the box, we avoid much of the confusion and exasperation that Schroedinger's thought experiment evokes. Hawking wrote, "When I hear of Schroedinger's cat, and I reach for my gun." Even Einstein was repelled by quantum uncertainty. DeBroglie especially held out for an interpretation of quantum physics which supported concreteness. We rebel against the idea of a universe based on uncertainty, and we seek to assure ourselves that what we experience is a concrete reality.
However, if the nuocontinuum is the observer that resolves the quantum uncertainty, our own individual sense of uncertainty is also resolved. The collapse of the particle wave function (the coming into being of the particle at a particular point in space-time) would be a function of the nuocontinuum acting as a whole, rather than as a local observer. The nuocontinuum is the observer who actualized creation the cosmic event in the box prior to the development of human consciousness. It is that cosmic observer who unifies the quantum effects of the electronuclear forces and the cosmic effects of gravity.
The Nuocontinuum, then, designates an unlimited, infinite connecting principle that binds all that is. Because it accounts for the material characteristics of the cosmos, it is "Creator." Because it presents itself through the agency of human consciousness, it may be sensed as Person and named Holy Spirit or Great Mystery. It is the source of that compelling "passion" of which Teilhard spoke, "to become one with the world that envelops us." Thus, though well beyond the scope of this article, the concept has implications for depth psychology and for theology. It has potential to help humans globally recapture a sense of meaning to human life, and to understand the experiences of those whose terminologies differ. Unless we do so, or at least critical masses of us do, we remain at great risk for destroying ourselves.
But its implications for the healing arts are also profound, for it makes us look at familiar concepts in quite a different light. In its affirmation of meaningful order in the cosmos as a whole, the nuocontinuum concept gives further definition and import to homeostasis as a healing, balancing principle that has more than physiological significance. When we invoke the term "placebo effect" we (usually unwittingly) are invoking a principle of the connectedness between an intervention and an effect, which now can be named and conceptualized. "Spontaneous remissions" of disease would be seen as something less than miracles but clearly more than merely chemical. After all, if physics can reach a limit to its powers of description, so too must be psychoneuroimmunology.
Practitioners, have become aware of the connectedness principle, we will become more aware that our own attitudes and approaches are significant to treatment outcomes and patient satisfaction. We will then realize that even though an experiment may be "doubly-blind" to some experimenters and to some persons being tested, there may be other influences outside the cause-effect "loop" and connections of which other persons may be conscious. Further, we will better understand that there are different levels of connectivity at work in every action, which require different levels of description to explain. And we might become more sensitive to patient's hopes and expectations that so are often stated in religious terms.
At this point in our harvest of knowledge, this synthesis is quite intuitive and speculative. However, even highly abstract drawings are often helpful in organizing thought. I hope that through some such synthesis as this, couched in whatever language, we will be given that courage to which Dossey eludes, to enter the "doorway through which we may encounter a radically new understanding of the physical world and our place in it." And, ones hope, assure the continued development of our abilities, together, to offer help to all in need of healing.
We collectively glorify our ability to think as the distinguishing characteristic of humanity; we personally and mistakenly glorify our thoughts as the distinguishing pattern of whom we are. From the inner voice of thought-as-words to the wordless images within our minds, thoughts create and limit our personal world. Through thinking we abstract and define reality, reason about it, react to it, recall past events and plan for the future. Yet thinking remains both woefully underdeveloped in most of us, as well as grossly overvalued. We can best gain some perspective on thinking in terms of energies.
We are hanging in language. We are suspended in language in such a way that we cannot say what is up and what is down, Niels Bohr lamented in the 1920s when confronted with the paradoxes, absurdities, and seeming impossibilities encountered in the then newly discovered quantum domain. The problem, he insisted, was not the quantum wonderland itself, but our language, our ways of thinking and talking about it. His colleague, Werner Heisenberg, went a step further and proclaimed that events in the quantum wonderland are not only unspeakable, they are unimaginable.
The same situation confronts today us when we try to talk about consciousness and how it relates to matter-energy. Go fishing for consciousness using the net of language and it always, inevitably, slips through the holes in our net. The limits of language-and imagination in talk about consciousness have been recently underlined, yet again, by the exchanges between philosopher Mark Woodhouse and physician Larry Dossey in the pages of Network.
Essentially, both men take opposing positions regarding the appropriateness of "energy talk" as a way of describing or explaining consciousness or mental phenomena. Woodhouse defends the use of energy talk (and proposes what he seems to think is a novel solution); Dossey denies the appropriateness of talking about consciousness in terms of energy. In for Woodhouse, consciousness is energy ("each is the other"); for Dossey, consciousness is not energy. As a philosopher passionately committed to exploring the relationship between consciousness and matter, between mind and body, and, specifically, the question "Can we have a science of consciousness?" I think the dialogue between Woodhouse and Dossey opens up a crucially important issue for philosophy of mind and for a science of consciousness. I believe the "energy question" is central to any significant advance we may make into understanding consciousness and how it relates to the physical world.
This relationship, is nevertheless, accredited by a double-aspect perspective: "Energy is the 'outside' of consciousness and consciousness is the 'inside' of energy throughout the universe." But making or that we have fallen into a fundamental philosophical error. As of urging to entice us for which we hold to bind of a particularly atypical sensibility for engaging the encounter with the narratives that belong to some "energy talk" about consciousness. But this study as at times happens to be of something to mention as a double-prospective that foregoes the most important point, and thereby fails to acknowledge what it is of true philosophically and by virtue of its existing character whose value we model.
A major challenge facing philosophers and scientists of consciousness (and anybody else who wishes to talk about it) is finding appropriate concepts, words and metaphors. So much of our language is derived from our two most dominant senses: vision and touch. Vision feeds language with spatial metaphors, while touch-or rather, kinesthetics-feeds language with muscular push-pull metaphors. The visuo-muscular senses dominate our perception and interaction with the world, and consequently metaphors derived from these senses dominate our ways of conceiving and talking about the world. It is no accident that spatial and mechanical descriptions and explanations predominate in physics-the paradigm science (and our culture's paradigm for all knowledge). Given our evolutionary heritage, with its selective bias toward vision and kinesthetics, we live predominantly in a spatial-push-pull world-the world of classical mechanics, a "billiard-ball" universe of moving, colliding, and recoiling massive bodies. Ours is a world of matter in motion, of things in space acted on by physical forces.
It should not be surprising, then, that when we come to talk about consciousness, our grooves of thinking channels us toward physics-talk-expressed today as "energy talk." Forces are felt-experienced in the body and we are tempted to think that the experience of force is identical to the energy exchanges between bodies described by physics. But this is to confuse the feeler's feeling (the subject) with what is felt (the object). More on this later.
Previously mentioned, was that the Woodhouse-Dossey debate highlights yet again the limits of language when we try to talk about consciousness. This problem is at least as old as Descartes' mind-body dualism (though, as we will see, it is not confined to Cartesian dualism-it is there, too, in forms of idealism known as the "Perennial Philosophy"). When Descartes made his famous distinction between mind and matter, he found himself "suspended in the language" of physics. He could find no better way to define mind than negatively in the terminology of physics. He defined matter as that which occupies space"res’ extensa," extended things. He defined the mental world as "res comitans," thinking things-and thinking things differ from physical things in that they do not occupy space. The problem was how could material, physical, things interact with nonphysical things? What conceivably could be the nature of their point of contact-material or mental? Centuries later, Freud, too, resorted to physics-energy talk when to specify the "mechanisms" and dynamics of the psyche-e.g. his concept of the libido. Today, the same tendency to use energy technologically to converse in talking, as Dossey points out, is rife in much new age talk about consciousness, soul, and spirit, exemplified in Woodhouse's article and his book Paradigm Wars.
Because of our reliance on the senses of vision and kinesthetics, we have an evolutionary predisposition, it seems, to talk in the language of physics or mechanics-and by that I mean "matter talk," or "energy talk." Yet all such talk seems to miss something essential when we come to speak of phenomena in the domain of the mind-for example, emotions, desires, beliefs, pains, and other felt qualities of consciousness. The inappropriate chunkiness of mechanistic metaphors borrowed from classical physics seems obvious enough. The mind just isn't at all like matter or machines, as Descartes was keenly aware. But then came Einstein's relativity, and the quantum revolution. First, Einstein's E = mc2 showed that matter was a form of energy, and so, with the advent of quantum theory, the material world began to dissolve into unimaginable, paradoxical bundles of energy or action. Matter itself was now understood to be a ghostly swirl of energy, and began to take on qualities formerly associated with mind. A great physicist, Sir James Jeans, even declared that "universe begins to look more like a great thought." Quantum events were so tiny, so undetermined, so un-mechanical in the classical sense, they seemed just the sort of thing that could respond to the influence of the mind.
The quantum-consciousness connection was boosted further by the need (at least in one interpretation of quantum theory) to include the observer (and his/her consciousness) in any complete description of the collapse of the quantum wave function. According to this view, the quantum system must include the consciousness of the observer. Ghostly energy fields from relativity and the quantum-consciousness connection triggered the imaginations of pop-science writers and dabblers in new age pseudo-science: Quantum theory, many believe, has finally opened the way for science to explore and talk about the mind. But the excitement was-and is-premature. It involves the linguistic and conceptual sleight-of-hand, whereas the clucky mechanical language that is in fact a matter that was obviously at best in metaphoric principles, just when applied to consciousness, it now seemed more reasonable to use the language of energy literally-particularly if cloaked in the "spooky" garb of quantum physics. But this shift from "metaphorical matter" to "literal energy" was unwarranted, unfounded, and deceptive.
Dissolving matter into energy makes neither of them are less conceptual. And the mark of the physical, as Descartes had pointed out, is that it is extended in space. Despite the insuperable problems with his dualism, Descartes' key insight remains valid: What distinguishes mind from matter is precisely that it does not occupy space. And this distinction holds just as fast between mind and energy-even so-called subtle energy (hypothetical "subtle energy" bodies are described as having extension, and other spatial attributes such as waves, vibrations, frequencies). Energy, even in the form of infinitesimal quanta or "subtle vibrations," still occupies space. And any theory of energy as a field clearly makes it spatial. Notions of "quantum consciousness" or "field consciousness"-and Woodhouse's "vibrations," "ripples," or "waves" of consciousness-therefore, are no more than vacuous jargon because they continue to fail to address the very distinction that Descartes formulated nearly four hundred years ago.
But that's not even the most troublesome deficiency of energy talk. It is equitably to suppose that physicists were proficient to show that quanta of energy did not occupy space; Suppose the behaviour of quanta was so bizarre that they could do all sorts of "non-physical" things-such as transcend space and time; Suppose that even if it could be shown that quanta were not "physical" in Descartes' sense . . . even supposing all of this, any proposed identity between energy and consciousness would still be invalid.
Energies talk fails to account for what is fundamentally most characteristic about consciousness, namely its subjectivity. No matter how fine-grained, or "subtle," energy could become, as an objective phenomenon it could never account for the fact of subjectivity-the "what-it-feels-like-from-within-experience." Ontologically, subjectivity cannot just emerge from wholly objective reality. Unless energy, at its ontologically most fundamental level, already came with some form of proto-consciousness, proto-experience, or proto-subjectivity, consciousness, experience, or subjectivity would never emerge or evolve in the universe.
Which brings us to Woodhouse's "energy monism" model, and the notion that "consciousness is the 'inside' of energy throughout the universe." Despite Dossey's criticism of this position, I think Woodhouse is here proposing a version of the only ontology that can account for a universe where both matter-energy and consciousness are real. He briefly summarizes why dualism, idealism, and materialism cannot adequately account for a universe consisting of both matter/energy and consciousness. (He adds "Epiphenomenalism" to these three as though it were distinctly ontological. It is not. Epiphenomenalism is a form of property dualism, which in turn is a form of materialism.) He then proceeds to outline a "fifth" alternative: "Energy monism." And although I believe his fundamental insight is correct, his discussion of this model in terms of double-aspectism falls victim to a common error in metaphysics: He confuses epistemology with ontology.
Woodhouse proposes that the weaknesses of the other ontologies-dualism, idealism, and materialism-can be avoided by adopting a "double-aspect theory that does not attempt to reduce either energy or consciousness to the other." And he goes on to build his alternative ontology on a double-aspect foundation. Now, I happen to be highly sympathetic with double-aspectism: It is a coherent and comprehensive (even "holistic") epistemology. As a way of knowing the world, double-aspectism opens up the possibility of a complementarity of subjective and objective perspectives.
But a perspective on the world yields epistemology-it reveals’ something about how we know what we know about the world. It does not reveal the nature of the world, which is the aim of ontology. Woodhouse makes an illegitimate leap from epistemology to ontology when he says, "This [energy monism] is a dualism of perspective, not of fundamental stuff," and concludes that "each is the other." Given his epistemological double-aspectism, the best Woodhouse can claim to be an ontological agnostic (as, in fact, Dossey does). He can talk about viewing the world from two complementary perspectives, but he cannot talk about the nature of the world in itself. Certainly, he cannot legitimately conclude from talk about aspects or perspectives that the ultimate nature of the world is "energy monism" or that "consciousness is energy." Epistemology talk cannot yield ontology talk-as Kant, and later Bohr, were well aware. Kant said we cannot know the thing-in-itself. The best we can hope for is to know some details about the instrument of knowing. Bohr said that the task of quantum physics is not to describe reality as it is in itself, but to describe what we can say about reality.
The issue of whether energy talk is appropriate for consciousness is to resolve ontologically not epistemological ly. At issue is whether consciousness is or is not a form of energy-not whether it can be known from different perspectives. If it is a form of energy, then energy talk is legitimate. If not, energy talk is illegitimate. But the nature of consciousness is not to be "determined by perspective," as Woodhouse states: "insides and outsides are determined by perspectives." If "insides" (or "outsides") were merely a matter of perspective, then any ontology would do, as long as we allowed for epistemological dualism or complementarity (though, of course, the meaning of "inside" and "outside" would differ according to each ontology). What Woodhouse doesn't do (which he needs to do to make his epistemology grow ontological legs) has established an ontology compatible with his epistemology of "inside" and "outside." In short, he needs to establish an ontological distinction between consciousness and energy. But this is precisely what Woodhouse aim to avoid with his model of energy monism. Dossey is right, I think, to describe energy talk about consciousness as a legacy of Newtonian physics (i.e., of visuo-kinesthetic mechanics). This applies equally to "classical energy talk," "quantum-energy talk," "subtle-energy talk," and Woodhouse's "dual-aspect energy talk." In an effort to defend energy talk about consciousness, Woodhouse substitutes epistemology for ontology, and leaves the crucial issue unresolved.
Unless Woodhouse is willing to ground his double-aspect epistemology in an ontological complementarity that distinguishes mind from matter, but does not separate them, he runs the risk of unwittingly committing "reductionism all over again"-despite his best intentions. In fact, Woodhouse comes very close to proposing just the kind of complementary ontology his model needs: "Consciousness isn't just a different level or wave form of vibrating energy; it is the 'inside' of energy-the pole of interiority perfectly understandable to every person who has had a subjective experience of any kind" (emphasis added). This is ontology talk, not epistemology talk. Woodhouse's error is to claim that the distinction "inside" (consciousness) and "outside" (energy) is merely a matter of perspective.
In order to defend his thesis of "energy monism," Woodhouse seems to want it both ways. On the one hand, he talks of being conscious and energy being ontologically identical"each is the other"; on the other, he makes a distinction between consciousness and energy: Energy is the 'outside' of consciousness and consciousness is the 'inside' of energy. He attempts to avoid the looming contradiction of consciousness and energy being both "identical yet distinct" by claiming that the identity is ontological while the distinction is epistemological. But the distinction cannot be merely epistemological-otherwise, as already pointed out, any ontology would do. But this is clearly not Woodhouse's position. Energy monism, as proposed by Woodhouse, is an ontological claim. Woodhouse admits as much when he calls energy monism "a fifth alternative" to the ontologism of dualism, idealism, materialism (and Epiphenomenalism [sic]) which he previously dismissed.
Furthermore, Woodhouse "inside" and "outside" are not merely epistemological when he means them to be synonyms for "subjectivity" and "objectivity" respectively. Although subjectivity and objectivity are epistemological perspectives, they are not only that. Subjectivity and objectivity can have epistemological meaning only if they refer to some implications of a primary ontological distinction-between what Sartre (1956) called the "for-itself" and the "in-itself," between that which feels and that which is felt. Despite his claims to the contrary, Woodhouse's distinction between "inside" and "outside" is ontological-not mere epistemological. And as an ontological distinction between consciousness and energy, it is illegitimate to conclude from his double-aspect epistemology the identity claim that "consciousness is energy." Woodhouse's consciousness-energy monism confusion, it seems to me, is a result of: (1) a failure to distinguish between non-identity and separation, and (2) a desire to avoid the pitfalls of Cartesian dualism. The first is a mistake, the second is not-but he conflates the two. He seems to think that if he allows for a non-identity between consciousness and energy this is tantamount to their being ontologically separate (as in Cartesian dualism). But (1) does not encompass that of (2): Ontological distinction does not entail separation. It is possible to distinguish two phenomena (such as the form and substance of a thing), yet recognize them as inseparable elements of a unity. Unity does not mean identity, and distinction does not mean separation. (I will return to this point shortly.) This muddle between epistemology and ontology is my major criticism of Woodhouse's position. Though if he had the courage or foresight to follow through on his epistemological convictions, and recognize that his position is compatible with (and would be grounded by) an ontological complementarity of consciousness and energy.
The ontological level of understanding (though explicitly denied) in Woodhouse's double-aspect model-where consciousness ("inside") and energy (“outside”) is actual throughout the universe is none other than panpsychism, or what has been variously called pan experientialism (Griffin, 1997) and radical materialism (de Quincey, 1997). It is the fourth alternative to the major ontologism of dualism, idealism, and materialism, and has a very long lineage in the Western philosophical tradition-going all the way back to Aristotle and beyond to the Presocratics. Woodhouse does not acknowledge any of this lineage, as if his double-aspect model was a novel contribution to the mind-matter debate. Besides Aristotle's hylemorphism, he could have referred to Leibniz' monads, Whitehead "actual occasion," and de Chardin's "tangential energy" and the "within" as precursors to the distinction he makes between "inside" and "outside." This oversight weakens the presentation of his case. Of course, to have introduced any or all of these mind-body theories would have made Woodhouse's ontological omission all the more noticeable.
One other weakness in Woodhouse's article is his reference to the Perennial Philosophy and the Great Chain of Being as supportive of energy talk that unites spiritual and physical realities. "The non-dual Source of some spiritual traditions . . . is said to express itself energetically (outwardly) on different levels in the Great Chain of Being (matter being the densest form of energy) . . ." Woodhouse is here referring to the many variations of idealist emanationism, where spirit is said to pour itself forth through a sequence of ontological levels and condense into matter. But just as I would say Woodhouse's energy monism unwittingly ultimately entails physicalist reductionism, my criticism of emanationism is that it, too, ultimately "physicalizes" spirit-which no idealist worth his or her salt would want to claim. Energy monism runs the same risk of "physicalizing" spirit as emanationism. So I see no support for Woodhouse's position as an alternative to dualism or materialism coming from the Perennial Philosophy. Both run the risk of covert dualism or covert materialism.
Dossey's critique of Woodhouse's energy monism and energy talk, particularly his caution not to assume that the "nonlocal" phenomena of quantum physics are related to the "nonlocal" phenomena of consciousness and distant healing other than a commonalty of terminology is sound. The caution is wise. However, his critique of Woodhouse's "inside" and "outside" fails to address Woodhouse's confusing epistemology and ontology. If Dossey saw that Woodhouse's intent was to confine the "inside/outside" distinction to epistemology, he might not have couched his critique in ontological terms. Dossey says, "By emphasizing inside and outside, interior and exterior, we merely create new boundaries and interfaces that require their own explanations." The "boundaries and interfaces" Dossey is talking about being ontological, not epistemological. And to this extent, Dossey's critique misses the fact that Woodhouse is explicitly engaged in epistemology talk. On the other hand, Dossey is correct to assume that Woodhouse's epistemological distinction between "inside and outside" necessarily implies an ontological distinction-between "inside" (consciousness) and "outside" energy.
Dossey's criticism of Woodhouse's energy monism, thus, rests on an ontological objection: Even if we do not yet have any idea of how to talk ontologically about consciousness, we at least know that (despite Woodhouse's contrary claim) consciousness and energy are not ontologically identical. There is an ontological distinction between "inside/consciousness" and "outside/energy." Thus, Dossey concludes, energy talk (which is ontological talk) is inappropriate for consciousness. On this, I agree with Dossey, and disagree with Woodhouse. However, Dossey goes on to take issue with Woodhouse's "inside/outside" distinction as a solution to the mind-body relation. If taken literally, Dossey's criticism is valid: "Instead of grappling with the nature of the connection between energy and consciousness, we are now obliged to clarify the nature of the boundary between 'inside' and 'outside' . . ." But I suspect that Woodhouse uses the spatial concepts "inside/outside" metaphorically because like the rest of us he finds our language short on nonphysical metaphors (though, as we will see, nonspatial metaphors are available).
It may be, of course, that Woodhouse has not carefully thought through the implications of this spatial metaphor, and how it leaves him open to just the sort of critique that Dossey levels. Dossey, I presume, is as much concerned with Woodhouse's claim that "consciousness is energy," meaning it is the "inside" of energy, as he is about the difficulties in taking the spatial metaphor of "inside/outside" literally. On the first point, I share Dossey's concern. I am less concerned about the second. As long as we remember that talk of "interiority" and "exteriority" are metaphors, I believe they can be very useful ways of pointing toward a crucial distinction between consciousness and energy.
The metaphor becomes a problem if we slip into thinking that it points to a literal distinction between two kinds of "stuff" (as Descartes did), or indeed to a distinction revealing two aspects of a single kind of "stuff." This latter slip seems to be precisely the mistake that Woodhouse makes with his energy monism. By claiming that consciousness is energy, Woodhouse in effect-despite his best intentions to the contrary-succeeds in equating (and this means "reducing") consciousness to physical "stuff." His mistake-and one that Dossey may be buying into-is to use "stuff-talk" for consciousness. It is a logical error to conclude from (1) there is only one kind of fundamental "stuff" (call it energy), and (2) this "stuff" has an interiority (call it consciousness), that (3) the interiority is also composed of that same "stuff” -, i.e., that consciousness is energy. It could be that "interiority/consciousness" is not "stuff" but something more collectively distinct ontologically-for examples, feeling or process-something which is intrinsic to, and therefore inseparable from, the "stuff." It could be that the world is made up of stuff that feels, where there is an ontological distinction between the feeling (subjectivity, experience, consciousness) and what is felt (objectivity, matter-energy).
Dossey's rejection of the "inside/outside" metaphor seems to presume (Ă la Woodhouse) that "inside" means the interior of some "stuff" and is that "stuff"-in this case, energy-stuff. But that is not the position of panpsychist and process philosophers from Leibniz down through Bergson, James, and Whitehead, to Hartshorns and Griffin. If we make the switch from a "stuff-oriented" to a process oriented ontology, then the kind of distinction between consciousness and energy dimly implicit in Woodhouse's model avoids the kind of criticism that Dossey levels at the "inside/outside" metaphor. Process philosophers prefer to use "time-talk" over "space-talk." Instead of talking about consciousness in terms of "insides," they talk about "moments of experience" or "duration." Thus, if we view the relationship between consciousness and energy in terms of temporal processes rather than spatial stuff, we can arrive at an ontology similar to Whiteheads relationship between consciousness and energy is understood as temporal. It is the relationship between subjectivity and objectivity, where the subject is the present state of an experiential process, and the object is its prior state. Substitute "present" for "interior" and "past" or "prior" for "exterior" and we have a process ontology that avoids the "boundary" difficulties raised by Dossey. (There is no boundary between past and present-the one flows into the other; the present incorporates the past.) From the perspective of panpsychism or radical materialism, consciousness and energy, mind and matter, subject and object always go together. All matter-energy is intrinsically sentient and experiential. Sentience-consciousness and matter-energy are inseparable, but nevertheless distinct. On this view, consciousness is the process of matter-energy informing itself.
Although our language is biassed toward physics-energy talk, full of mechanistic metaphors, this is clearly not the whole story. The vernacular of the marketplace, as well as the language of science itself, is also rich with non-mechanistic metaphors, metaphors that flow direct from experience itself. Ironically, not only do we apply these consciousness metaphors to the mind and mental events, but also to the world of matter in our attempts to understand its deeper complexities and dynamics. For example, systems theory and evolutionary biology-even at the reductionist level of molecular genetics-are replete with words such as "codes," "information," "meaning," "self-organizing," and the p-word: "purpose." So we are not limited to mechanistic metaphors when describing either the world of matter or the world of mind. But-and this is the important point-because of our bias toward visuo-muscular images, we tend to forget that metaphors of the mind are sui generis, and, because of our scientific and philosophical bias in favour of a mechanism, we often attempt to reduce metaphors of the mind to metaphors of matter. My proposal for consciousness talk is this: Recognize the limitations of mechanistic metaphors, and the inappropriateness of literal energy talk, when discussing consciousness. Instead, acknowledge the richness and appropriateness of metaphors of meaning when talking about the mind. In short: Drop mechanistic metaphors (energy talk) and take up meaning metaphors (consciousness talk) when talking about consciousness.
One of the thorniest issues in "energy" and "consciousness" work is the tendency to confuse the two. Consciousness does not equal energy, yet the two are inseparable. Consciousness is the "witness" which experiences the flow of energy, but it is not the flow of energy. We might say consciousness is the felt interiority of energy/matter - but it is not energy.
If we say that consciousness is a form of energy, then we have two options. Either It is a physical form of energy (even if it is very subtle energy), or It is not a physical form of energy. If we say that consciousness is a form of energy that is physical, then we are reducing consciousness (and spirit) to physics. And few of us, unless we are materialists, want to do that. If we say that consciousness is a form of energy that is not physical, then we need to say in what way psychic energy differs from physical energy. If we cannot explain what we mean by "psychic energy" and how it is different from physical energy, in that then we should ask ourselves why use the term "energy" at all? Our third alternative is to say that consciousness is not a form of energy (physical or nonphysical). This is not to imply that consciousness has nothing to do with energy. In fact, the position I emphasize in my graduate classes is that consciousness and energy always go together. They cannot ever be separated. But this is not to say they are not distinct. They are distinct-energy is energy, consciousness is consciousness-but they are inseparable (like two sides of a coin, or, better, like the shape and substance of a tennis ball. You can't separate the shape from the substance of the ball, but shape and substance are definitely distinct).
So, for example, if someone has a kundalini experience, they may feel a rush of energy up the chakra system . . . but to say that the energy flow is consciousness is to mistake the object (energy flow) for the subject, for what perceives (consciousness) the object. Note the two importantly distinct words in the phrase "feel the rush of energy . . . "On the one hand there is the "feeling" (or the "feeler"), on the other, there is what is being felt or experienced (the energy). Even our way of talking about it reveals that we detect a distinction between feeling (consciousness) and what we feel (energy). Yes, the two go together, but they are not the same. Unity, or unification, or holism, does not equal identity. To say that one aspect of reality (say, consciousness) cannot be separated from another aspect of reality (say, matter-energy) is not to say both aspects of reality (consciousness and matter-energy) are identical.
Consciousness, is neither identical to energy (monism) nor it a separate substance or energy in addition to physical matter or energy (dualism)-it is the "interiority," the what-it-feels-like-from-within, the subjectivity that is intrinsic to the reality of all matter and energy (panpsychism or radical materialism). If you take a moment to pay attention to what's going on in your own body right now, you'll see-or feel-what I mean: The physical matter of your body, including the flow of whatever energies are pulsing through you, is the "stuff" of your organism. But there is also a part of you that is aware of, or feels, the pumping of your blood (and other energy streams). That aspect of you that feels the matter-energy in your body is your consciousness. We could express it this way: "Consciousness is the process of matter-energy informing itself." Consciousness is the ability that matter-energy has to feel, to know, and to direct itself. The universe could be (and probably is) full of energy flows, vortices, and vibrations, but without consciousness, all this activity would be completely unfelt and unknown. Only because there is consciousness can the flow of energy be felt, known, and purposefully directed.
Over the past three decades, philosophy of science has grown increasingly "local." Concerns have switched from general features of scientific practice to concepts, issues, and puzzles specific to particular disciplines. Philosophy of neuroscience is a natural result. This emerging area was also spurred by remarkable recent growth in the neuroscience. Cognitive and computational neuroscience continues to encroach upon issues traditionally addressed within the humanities, including the nature of consciousness, action, knowledge, and normativity. Empirical discoveries about brain structure and function suggest ways that "naturalistic" programs might develop in detail, beyond the abstract philosophical considerations in their favour
The literature distinguishes "philosophy of neuroscience" and "neurophilosophy." The former concern foundational issues within the neuroscience. The latter concerns application of neuroscientific concepts to traditional philosophical questions. Exploring various concepts of representation employed in neuroscientific theories is an example of the former. Examining implications of neurological syndromes for the concept of a unified self is an example of the latter. In this entry, we will assume this distinction and discuss examples of both.
Contrary to some opinion, actual neuroscientific discoveries have exerted little influence on the details of materialist philosophies of mind. The "neuroscientific milieu" of the past four decades has made it harder for philosophers to adopt dualism. But even the "type-type" or "central state" identity theories that rose to brief prominence in the late 1950s drew upon few actual details of the emerging neuroscience. Recall the favourite early example of a psychoneural identity claim: pain is identical to C-fibre firing. The "C fibres" turned out to be related to only a single aspect of pain transmission. Early identity theorists did not emphasize psychoneural identity hypotheses, admitting that their "neuro" terms were placeholder for concepts from future neuroscience. Their arguments and motivations were philosophical, even if the ultimate justification of the program was held to be empirical.
The apology for this lacuna by early identity theorists was that neuroscience at that time was too nascent to provide any plausible identities. But potential identities were afoot. David Hubel and Torsten Wiesel's (1962) electro physiological demonstrations of the receptive field properties of visual neurons had been reported with great fanfare. Using their techniques, neuro physiologists began discovering neurons throughout visual cortex responsive to increasingly abstract features of visual stimuli: from edges to motion direction to colours to properties of faces and hands. More notably, Donald Hebb had published The Organization of Behaviour (1949) a decade earlier. Therein he offered detailed explanations of psychological phenomena in terms of known neural mechanisms and anatomical circuits. His psychological explananda included features of perception, learning, memory, and even emotional disorders. He offered these explanations as potential identities. One philosopher did take note of some available neuroscientific detail was Barbara Von Eckardt-Klein (1975). She discussed the identity theory with respect to sensations of touch and pressure, and incorporated then-current hypotheses about neural coding of sensation modality, intensity, duration, and location as theorized by Mountcastle, Libet, and Jasper. Yet she was a glaring exception. Largely, available neuroscience at the time was ignored by both philosophical friends and foes of early identity theories.
Philosophical indifference to neuroscientific detail became "principled" with the rise and prominence of functionalism in the 1970s. The functionalists' favourite argument was based on multiple reliability: a given mental state or event can be realized in a wide variety of physical types (Putnam, 1967 and Fodor, 1974). So a detailed understanding of one type of realizing physical system (e.g., brains) will not shed light on the fundamental nature of mind. A psychological state-type is autonomous from any single type of its possible realizing physical mechanisms. Instead of neuroscience, scientifically-minded philosophers influenced by functionalism sought evidence and inspiration from cognitive psychology and "program-writing" artificial intelligence. These disciplines résumé being of themselves away from underlying physical mechanisms and emphasize the "information-bearing" properties and capacities of representations (Haugeland, 1985). At this same time neuroscience was delving directly into cognition, especially learning and memory. For example, Eric Kandel (1976) proposed parasynaptic mechanisms governing transmitter release rates as a cell-biological explanation of simple forms of associative learning. With Robert Hawkins (1984) he demonstrated how cognitivist aspects of associative learning (e.g., Forming, second-order conditioning, overshadowing) could be explained cell-biologically by sequences and combinations of these basic forms implemented in higher neural anatomies. Working on the postsynaptic side, neuroscientists began unravelling the cellular mechanisms of long term potentiation (LTP). Physiological psychologists quickly noted its explanatory potential for various forms of learning and memory. Yet few "materialist" philosophers paid any attention. Why should they? Most were convinced functionalists, who believed that the "engineering level" details might be important to the clinician, but were irrelevant to the theorist of mind.
A major turning point in philosophers' interest in neuroscience came with the publication of Patricia Churchland's Neurophilosophy (1986). The Churchlands (Pat and husband Paul) were already notorious for advocating eliminative materialism. In her (1986) book, Churchland distilled eliminativist arguments of the past decade, unified the pieces of the philosophy of science underlying them, and sandwiched the philosophy between a five-chapter introduction and neuroscience and a 70-page chapter on three then-current theories of brain function. She was unapologetic about her intent. She was introducing philosophy of science to neuroscientists and neuroscience to philosophers. Nothing could be more obvious, she insisted, than the relevance of empirical facts about how the brain works to concerns in the philosophy of mind. Her term for this interdisciplinary method was "co-evolution" (borrowed from biology). This method seeks resources and ideas from anywhere on the theory hierarchy above or below the question at issue. Standing on the shoulders of philosophers like Quine and Sellars, Churchland insisted that specifying some point where neuroscience ends and philosophy of science begins is hopeless because the boundaries are poorly defined. neuro philosophers would carefully choose resources from both disciplines as they saw fit.
Three themes predominate Churchlands philosophical discussion: Developing an alternative to the logical empiricist theory of intertheoretic cause to be connected to property-dualistic arguments based on subjectivity and sensory qualia, and responding to anti-reductionist multiple reliability arguments. These projects have remained central to neurophilosophy over the past decade. John Bickle (1998) extends the principal insight of Clifford Hooker's (1981) post-empiricist theory of intertheoretic reduction. He quantifies key notions using a model-theoretic account of theory structure adapted from the structuralist program in philosophy of science. He also makes explicit the form of argument scientist’s employ to draw ontological conclusions (cross-theoretic identities, revisions, or eliminations) based on the nature of the intertheoretic reduction relations obtaining in specific cases. For example, physicists concluded that visible light, a theoretical posit of optics, is electromagnetic radiation within specified wavelengths, a theoretical posit of electromagnetism: a cross-theoretic ontological identity. In another case, however, chemists concluded that phlogiston did not exist: an elimination of a kind from our scientific ontology. Bickle explicates the nature of the reduction relation in a specific case using a semi-formal account of ‘an interior theoretic approximation’ inspired by structuralist results. Paul Churchland (1996) has carried on the attack on property-dualistic arguments for the ir reducibility of conscious experience and sensory qualia. He argues that acquiring some knowledge of existing sensory neuroscience increases one's ability to ‘imagine’ or ‘conceive of’ a comprehensive neurobiological explanation of consciousness. He defends this conclusion using a thought-experiment based on the history of optics and electromagnetism. Finally, the literature critical of the multiple reliability argument has begun to flourish. Although the multiple reliability argument remains influential among nonreductive physicalists, it no longer commanded the universal acceptance it once did. Replies to the multiple reliability argument based on neuroscientific details have appeared. For example, William Bechtel and Jennifer Mundale (1997, in press) argue that neuroscientists use psychological criteria in brain mapping studies. This fact undercuts the likelihood that psychological kinds are multiplying realized.
Eliminative materialism (EM) is the conjunction of two claims. First, our common sense ‘belief-desire’ conception of mental events and processes, our ‘folk psychology,’ is a false and misleading account of the causes of human behaviour. Second, like other false conceptual frameworks from both folk theory and the history of science, it will be replaced by, rather than smoothly reduced or incorporated into, a future neuroscience. Folk psychology is the collection of common homilies about the causes of human behaviour. You ask me why Marica is not accompanying me this evening. I reply that her grant deadline is looming. You nod sympathetically. You understand my explanation because you share with me a generalization that relates beliefs about looming deadlines, desires about meeting professionally and financially significant ones, and ensuing free-time behaviour. It is the collection of these kinds of homilies that EM claims to be flawed beyond significant revision. Although this example involves only beliefs and desires, folk psychology contains an extensive repertoire of propositional attitudes in its explanatory nexus: hopes, intentions, fears, imaginings, and more. To the extent that scientific psychology (and neuroscience) retains folk concepts, EM applies to it as well.
EM is physicalist in the classical sense, postulating some future brain science as the ultimately correct account of (human) behaviour. It is eliminative in predicting the future removal of folk psychological kinds from our post-neuroscientific ontology. EM proponents often employ scientific analogies. Oxidative reactions as characterized within elemental chemistry bear no resemblance to phlogiston release. Even the "direction" of the two processes differ. Oxygen is gained when an object burns (or rusts), phlogiston was said to be lost. The result of this theoretical change was the elimination of phlogiston from our scientific ontology. There is no such thing. For the same reasons, according to EM, continuing development in neuroscience will reveal that there are no such things as beliefs and desires as characterized by common sense.
Here we focus only on the way that neuroscientific results have shaped the arguments for EM. Surprisingly, only one argument has been strongly influenced. (Most arguments for EM stress the failures of folk psychology as an explanatory theory of behaviour.) This argument is based on a development in cognitive and computational neuroscience that might provide a genuine alternative to the representations and computations implicit in folk psychological generalizations. Many eliminative materialists assume that folk psychology is committed to propositional representations and computations over their contents that mimic logical inferences. Even though discovering such an alternative has been an eliminativist goal for some time, neuroscience only began delivering on this goal over the past fifteen years. Points in and trajectories through vector spaces, as an interpretation of synaptic events and neural activity patterns in biological neural networks are key feature of this development. This argument for EM hinges on the differences between these notions of cognitive representation and the propositional attitudes of folk psychology (Churchland, 1987). However, this argument will be opaque to those with no background in contemporary cognitive and computational neuroscience, so we need to present a few scientific details. With these details in place, we will return to this argument for EM.
At one level of analysis the basic computational element of a neural network (biological or artificial) is the neuron. This analysis treats neurons as simple computational devices, transforming inputs into output. Both neuronal inputs and outputs reflect biological variables. For the remainder of this discussion, we will assume that neuronal inputs are frequencies of action potentials (neuronal "spikes") in the axons whose terminal branches synapse onto the neuron in question. Neuronal output is the frequency of action potentials in the axon of the neuron in question. A neuron computes its total input (usually treated mathematically as the sum of the products of the signal strength along each input line times the synaptic weight on that line). It then computes a new activation state based on its total input and current activation state, and a new output state based on its new activation value. The neuron's output state is transmitted as a signal strength to whatever neurons on which its axon synapses. The output state reflects systematically the neuron's new activation state.
Analysed at this level, both biological and artificial neural networks are interpreted naturally as vector-to-vector transformers. The input vector consists of values reflecting activity patterns in axons synapsing on the network's neurons from outside (e.g., from sensory transducers or other neural networks). The output vector consists of values reflecting the activity patterns generated in the network's neurons that project beyond the net (e.g., to motor effectors or other neural networks). Given that neurons' activity depends partly upon their total input, and total input depends partly on synaptic weights (e.g., parasynaptic neurotransmitter release rate, number and efficacy of postsynaptic receptors, availability of enzymes in synaptic cleft), the capacity of biological networks to change their synaptic pressures to initiate a plastic vector-to-vector transformer. In principle, a biological network with plastic synapses can come to implement any vector-to-vector transformation that its composition permits (number of input units, output units, processing layers, recurrence, cross-connections, etc.)
The anatomical organization of the cerebellum provides a clear example of a network amendable to this computational interpretation. The cerebellum is the bulbous convoluted structure dorsal to the brainstem. A variety of studies (behavioural, neuropsychological, single-cell electros), implicate this structure in motor integration and fine motor coordination. Mossy fibres (axons) from neurons outside the cerebellum synapse on cerebellular granule cells, which in turn project to parallel fibres. Activity patterns’ across the collection of mossy fibres (frequency of action potentials per time unit in each fibre projecting into the cerebellum) provide values for the input vector. Parallel fibres make multiple synapses on the dendritic trees and cell bodies of cerebellular Purkinje neurons. Each Purkinje neuron "sums" its post-synaptic potentials (PSPs) and emits a train of action potentials down its axon based (partly) on its total input and previous activation state. Purkinje axons project outside the cerebellum. The network's output vectors is thus the ordered values representing the pattern of activity generated in each Purkinje axon. Changes to the efficacy of individual synapses on the parallel fibres and the Purkinje neurons alter the resulting PSPs in Purkinje axons, generating different axonal spiking frequencies. Computationally, this amounts to a different output vector to the same input activity pattern (plasticity).
This interpretation puts the useful mathematical resources of dynamical systems into the hands of computational neuroscientists. Vector spaces are an example. For example, learning can be characterized fruitfully in terms of changes in synaptic weights in the network and subsequent reduction of error in network output. (This approach goes back to Hebb, 1949, although within the vector-space interpretation that follows.) A useful representation of this account is on a synaptic weight-error space, where one dimension represents the global error in the network's output to a given task, and all other dimensions represent the weight values of individual synapses in the network. Points in this multidimensional state space represent the global performance error correlated with each possible collection of synaptic weights in the network. As the weights change with each performance (in accordance with a biologically-implemented learning algorithm), the global error of network performance continually decreases. Learning is represented as synaptic weight changes correlated with a descent along the error dimension in the space (Churchland and Sejnowski, 1992). Representations (concepts) can be portrayed as partitions in multidimensional vector spaces. An example is a neuron activation vector space. A graph of such a space contains one dimension for the activation value of each neuron in the network (or some subset). A point in this space represents one possible pattern of activity in all neurons in the network. Activity patterns generated by input vectors that the network has learned to group together will cluster around a (hyper-) point or sub volume in the activity vector space. Any input pattern sufficiently similar to this group will produce an activity pattern lying in geometrical proximity to this point or sub volume. Paul Churchland (1989) has argued that this interpretation of network activity provides a quantitative, neurally-inspired basis for prototype theories of concepts developed recently in cognitive psychology.
Using this theoretical development, has offered a novel argument for EM. According to this approach, activity vectors are the central kind of representation and vector-to-vector transformations are the central kind of computation in the brain. This contrasts sharply with the propositional representations and logical/semantic computations postulated by folk psychology. Vectorial content is unfamiliar and alien to common sense. This cross-theoretic difference is at least as great as that between oxidative and phlogiston concepts, or kinetic-corpuscular and caloric fluid heat concepts. Phlogiston and caloric fluid are two "parade" examples of kinds eliminated from our scientific ontology due to the nature of the intertheoretic relation obtaining between the theories with which they are affiliated and the theories that replaced these. The structural and dynamic differences between the folk psychological and emerging cognitive neuroscientific kinds suggest that the theories affiliated with the latter will also correct significantly the theory affiliated with the former. This is the key premise of an eliminativist argument based on predicted intertheoretic relations. And these intertheoretic contrasts are no longer just an eliminativist's goal. Computational and cognitive neuroscience has begun to deliver an alternative kinematics for cognition, one that provides no structural analogue for the propositional attitudes.
Certainly the replacement of propositional contents by vectorial alternatives implies significant correction to folk psychology. But does it justifies EM? Even though this central feature of folk-psychologically posits in the finding of no analogues in one hot theoretical development in recent cognitive and computational neuroscience, there might be other aspects of cognition that folk psychology gets right. Within neurophilosophy, concluding that a cross-theoretic identity claim is true (e.g., folk psychological state F is identical to neural state N) or that an eliminativist claim is true (there is no such thing as folk psychological state F) depends on the nature of the intertheoretic reduction obtaining between the theories affiliated with the posits in question. But the underlying account of intertheoretic reduction recognizes a spectrum of possible reductions, ranging from relatively "smooth" through "significantly revisionary" to "extremely bumpy." Might the reduction of folk psychology and a "vectorial" neurobiology occupy the middle ground between "smooth" and "bumpy" intertheoretic reductions, and hence suggest a "revisionary" conclusion? The reduction of classical equilibrium thermodynamics to statistical mechanics to microphysics provides a potential analogy. John Bickle argues on empirical grounds that such a outcome is likely. He specifies conditions on "revisionary" reductions from historical examples and suggests that these conditions are obtaining between folk psychology and cognitive neuroscience as the latter develops. In particular, folk psychology appears to have gotten right the grossly-specified functional profile of many cognitive states, especially those closely related to sensory input and behavioural output. It also appears to get right the "intentionality" of many cognitive states - the object that the state is of or about - even though cognitive neuroscience eschews its implicit linguistic explanation of this feature. Revisionary physicalism predicts significant conceptual change to folk psychological concepts, but denies total elimination of the caloric fluid-phlogiston variety.
The philosophy of science is another area where vector space interpretations of neural network activity patterns have impacted philosophy. In the Introduction to his (1989) book, Paul Churchland asserts that it will soon be impossible to do serious work in the philosophy of science without drawing on empirical work in the brain and behavioural sciences. To justify this claim, he suggests neurocomputational reformulation of key concepts from this area. At the heart is a neurocomputational account of the structure of scientific theories. Problems with the orthodox "sets-of-sentences" view have been known for more than three decades. Churchland advocates replacing the orthodox view with one inspired by the "vectorial" interpretation of neural network activity. Representations implemented in neural networks (as discussed above) compose a system that corresponds to important distinctions in the external environment, are not explicitly represented as such within the input corpus, and allow the trained network to respond to inputs in a fashion that continually reduces error. These are exactly the functions of theories. Churchland is bold in his assertion: an individual's theory-of-the-world is a specific point in that individual's error-synaptic weight vector space. It is a configuration of synaptic weights that partitions the individual's activation vector space into subdivisions that reduce future error messages to both familiar and novel inputs.
This reformulation invites an objection, however. Churchland boasts that his theory of theories is preferable to existing alternatives to the orthodox "sets-of-sentences" account - for example, the semantic view (Suppe, 1974; van Fraassen, 1980) - because his is closer to the "buzzing brains" that use theories. But as Bickle notes, neurocomputational models based on the mathematical resources described above are a long way into the realm of abstractia. Even now, they remain little more than novel (and suggestive) applications of the mathematics of quasi-linear dynamical system to simplified schemata of brain circuitries. neuro philosophers owe some account of identifications across ontological categories before the philosophy of science community will accept the claim that theories are points in high-dimensional state spaces implemented in biological neural networks. (There is an important methodological assumption lurking in this objection.
Churchlands neurocomputational reformulation of scientific and epistemological concepts build on this account of theories. He sketches "neutralized" accounts of the theory-ladenness of perception, the nature of concept unification, the virtues of theoretical simplicity, the nature of Kuhnian paradigms, the kinematics of conceptual change, the character of abduction, the nature of explanation, and even moral knowledge and epistemological normativity. Conceptual redeployment, for example, is the activation of an already-existing prototype representation - a counterpoint or region of a partition of a high-dimensional vector space in a trained neural network - a novel type of input pattern. Obviously, we can't here do justice to Churchlands various attempts at reformulation. We urge the intrigued reader to examine his suggestions in their original form. But a word about philosophical methodology is in order. Churchland is not attempting "conceptual analysis" in anything resembling its traditional philosophical sense and neither, typically, are neuro philosophers. (This is why a discussion of neuro philosophical reformulation fits with a discussion of EM.) There are philosophers who take the discipline's ideal to be a relatively simple set of necessary and sufficient conditions, expressed in non-technical natural language, governing the application of important concepts (like justice, knowledge, theory, or explanation). These analyses should square, to the extent possible, with pre-theoretical usage. Ideally, they should preserve synonymy. Other philosophers view this ideal as sterile, misguided, and perhaps deeply mistaken about the underlying structure of human knowledge. neuro philosophers tend to reside in the latter camp. Those who dislike philosophical speculation about the promise and potential of nascent science in an effort to reformulate ("reform-ulate") traditional philosophical concepts have probably already discovered that neurophilosophy is not for them. But the charge that neurocomputational reformulation of the sort Churchland attempts are "philosophically uninteresting" or "irrelevant" because they fail to provide "adequate analyses" of theory, explanation, and the like will get ignored among many contemporary philosophers, as well as their cognitive-scientific and neuroscientific friends. Before we leave the neuro philosophical applications of this theoretical development from recent cognitive/computational neuroscience, one more point of scientific detail is in order. The popularity of treating the neuron as the basic computational unit among neural modelers, as opposed to cognitive modelers, is declining rapidly. Compartmental modelling enables computational neuroscientists to mimic activity in and interactions between patches of neuronal membrane. This endorses modelers to control and manipulate a variety of subcellular factors that determine action potentials per time unit (including the topology of membrane structure in individual neurons, variations in ion channels across membrane patches, field properties of post-synaptic potentials depending on the location of the synapse on the dendrite or soma). Modelers can "custom-build" the neurons in their target circuitry without sacrificing the ability to study circuit properties of networks. For these reasons, few serious computational neuroscientists continue to work at a level that treats neurons as unstructured computational devices. But the above interpretative points still stand. With compartmental modelling, not only are simulated neural networks interpretable as vector-to-vector transformers. The neurons composing them are, too.
The Philosophy of science, and scientific epistemology are not the only area where philosophers have lately urged the relevance of neuroscientific discoveries. Kathleen Akins argues that a "traditional" view of the senses underlies the variety of sophisticated "naturalistic" programs about intentionality. Current neuroscientific understanding of the mechanisms and coding strategies implemented by sensory receptors shows that this traditional view is mistaken. The traditional view holds that sensory systems are "veridical" in at least three ways. (1) Each signal in the system correlates with a small range of properties in the external (to the body) environment. (2) The structure in the relevant relations between the external properties the receptors are sensitive to is preserved in the structure of the relations between the resulting sensory states. And (3) the sensory system reconstructively in faithfully, without fictive additions or embellishments, the external events. Using recent neurobiological discoveries about response properties of thermal receptors in the skin as an illustration, Akins shows that sensory systems are "narcissistic" rather than "veridical." All three traditional assumptions are violated. These neurobiological details and their philosophical implications open novel questions for the philosophy of perception and for the appropriate foundations for naturalistic projects about intentionality. Armed with the known neurophysiology of sensory receptors, for example, our "philosophy of perception" or of "perceptual intentionality" will no longer focus on the search for correlations between states of sensory systems and "veridically detected" external properties. This traditional philosophical (and scientific) project rests upon a mistaken "veridical" view of the senses. Neuroscientific knowledge of sensory receptor activity also shows that sensory experience does not serve the naturalist well as a "simple paradigm case" of an intentional relation between representation and world. Once again, available scientific detail shows the naivety of some traditional philosophical projects.
Focussing on the anatomy and physiology of the pain transmission system, Valerie Hardcastle (1997) urges a similar negative implication for a popular methodological assumption. Pain experiences have long been philosophers' favourite cases for analysis and theorizing about conscious experience generally. Nevertheless, every position about pain experiences has been defended recently: eliminativist, a variety of objectivists view, relational views, and subjectivist views. Why so little agreement, despite agreement that pain experience is the place to start an analysis or theory of consciousness? Hardcastle urges two answers. First, philosophers tend to be uninformed about the neuronal complexity of our pain transmission systems, and build their analyses or theories on the outcome of a single component of a multi-component system. Second, even those who understand some of the underlying neurobiology of pain tends to advocate gate-control theories. But the best existing gate-control theories are vague about the neural mechanisms of the gates. Hardcastle instead proposes a dissociable dual system of pain transmission, consisting of a pain sensory system closely analogous in its neurobiological implementation to other sensory systems, and a descending pain inhibitory system. She argues that this dual system is consistent with recent neuroscientific discoveries and accounts for all the pain phenomena that have tempted philosophers toward particular (but limited) theories of pain experience. The neurobiological uniqueness of the pain inhibitory system, contrasted with the mechanisms of other sensory modalities, renders pain processing atypical. In particular, the pain inhibitory system dissociates pains sensation from stimulation of nociceptors (pain receptors). Hardcastle concludes from the neurobiological uniqueness of pain transmission that pain experiences are atypical conscious events, and hence not a good place to start theorizing about or analysing the general type.
Developing and defending theories of content is a central topic in current philosophy of mind. A common desideratum in this debate is a theory of cognitive representation consistent with a physical or naturalistic ontology. We'll here describe a few contributions neuro philosophers have made to this literature.
When one perceives or remembers that he is out of coffee, his brain state possesses intentionality or "aboutness." The percept or memory is about one's being out of coffee, and it represents one for being out of coffee. The representational state has content. A psychosemantics seeks to explain what it is for a representational state to be about something: to provide an account of how states and events can have specific representational content. A physicalist psychosemantics seeks to do this using resources of the physical sciences exclusively. neuro philosophers have contributed to two types of physicalist psychosemantics: the Functional Role approach and the Informational approach.
The core claim of functional roles of semantics holds that a representation has its content in virtue of relations it bears to other representations. Its paradigm application is to concepts of truth-functional logic, like the conjunctive ‘and’ or disjunctive ‘or.’ A physical event instantiates the ‘and’ function just in case it maps two true inputs onto a single true output. Thus an expression bears the relations to others that give it the semantic content of ‘and.’ Proponents of functional role semantics propose similar analyses for the content of all representations (Form 1986). A physical event represents birds, for example, if it bears the right relations to events representing feathers and others representing beaks. By contrast, informational semantics associates content to a state depending upon the causal relations obtaining between the state and the object it represents. A physical state represents birds, for example, just in case an appropriate causal relation obtains between it and birds. At the heart of informational semantics is a causal account of information. Red spots on a face carry the information that one has measles because the red spots are caused by the measles virus. A common criticism of informational semantics holds that mere causal covariation is insufficient for representation, since information (in the causal sense) is by definition, always veridical while representations can misrepresent. A popular solution to this challenge invokes a teleological analysis of ‘function.’ A brain state represents X by virtue of having the function of carrying information about being caused by X (Dretske 1988). These two approaches do not exhaust the popular options for a psychosemantics, but are the ones to which neuro philosophers have contributed.
Paul Churchlands allegiance to functional role semantics goes back to his earliest views about the semantics of terms in a language. In his (1979) book, he insists that the semantic identity (content) of a term derive from its place in the network of sentences of the entire language. The functional economies envisioned by early functional role semanticists were networks with nodes corresponding to the objects and properties denoted by expressions in a language. Thus one node, appropriately connected, might represent birds, another feathers, and another beaks. Activation of one of these would tend to spread to the others. As ‘connectionist’ network modelling developed, alternatives arose to this one-representation-per-node ‘localist’ approach. By the time Churchland provided a neuroscientific elaboration of functional role semantics for cognitive representations generally, he too had abandoned the ‘localist’ interpretation. Instead, he offered a ‘state-space semantics’.
We saw in the section just above how (vector) state spaces provide a natural interpretation for activity patterns in neural networks (biological and artificial). A state-space semantics for cognitive representations is a species of functional role semantics because the individuation of a particular state depends upon the relations obtaining between it and other states. A representation is a point in an appropriate state space, and points (or sub volumes) in a space are individuated by their relations to other points (locations, geometrical proximity). Churchland illustrates a state-space semantics for neural states by appealing to sensory systems. One popular theory in sensory neuroscience of how the brain codes for sensory qualities (like Collor) are the opponent process account. Churchland describes a three-dimensional activation vector state-space in which all Collor perceivable by humans is represented as a point (or sub value). Each dimension corresponds to activity rates in one of three classes of photoreceptors present in the human retina and their efferent paths: The red-green opponent pathway, yellow-blue opponent pathway, and black-white (contrast) opponent pathway. Photons striking the retina are transduced by the receptors, producing an activity rate in each of the segregated pathways. The characterized Cellos have a triplet of activation frequency rates. Each dimension in that three-dimensional space will represent average frequency of action potentials in the axons of one class of ganglion cells projecting out of the retina. Face-to-face, the Collor perceivable by humans will be a region of that space. For example, an orange stimulus produces a relatively low level of activity in both the red-green and yellow-blue opponent pathways (x-axis and y-axis, respectively), and middle-range activity in the black-white (contrast) opponent pathways (z-axis). Pink stimuli, on the other hand, produce low activity in the red-green opponent pathway, middle-range activity in the yellow-blue opponent pathway, and high activity in the black-white (contrast) an opponent pathway. The location of each colour in the space generates a ‘colour solid.’ Location on the solid and geometrical proximity between regions reflect structural similarities between the perceived colours. Human gustatory representations are points in a four-dimensional state space, with each dimension coding for activity rates generated by gustatory stimuli in each type of taste receptor (sweet, salty, sour, bitter) and their segregated efferent pathways. When implemented in a neural network with structural and hence computational resources as vast as the human brain, the state space approach to psychosemantics generates a theory of content for a huge number of cognitive states.
Jerry Fodor and Ernest LePore raise an important challenge to Churchlands psychosemantics. Location in a state space alone seems insufficient to fix a state's representational content. Churchland never explains why a point in a three-dimensional state space represents the Collor, as opposed to any other quality, object, or event that varies along three dimensions. Churchlands account achieves its explanatory power by the interpretation imposed on the dimensions. Fodor and LePore allege that Churchland never specifies how a dimension comes to represent, e.g., degree of saltiness, as opposed to yellow-blue wavelength opposition. One obvious answer appeals to the stimuli that form the ‘external’ inputs to the neural network in question. Then, for example, the individuating conditions on neural representations of colours are that opponent processing neurons receive input from a specific class of photoreceptors. The latter in turn have electromagnetic radiation (of a specific portion of the visible spectrum) as their activating stimuli. However, this appeal to ‘external’ stimuli as the ultimate individuating conditions for representational content makes the resulting approach a version of informational semantics. Is this approach consonant with other neurobiological details?
The neurobiological paradigm for informational semantics is the feature detector: One or more neurons that are (i) maximally responsive to a particular type of stimulus, and (ii) have the function of indicating the presence of that stimulus type. Examples of such stimulus-types for visual feature detectors include high-contrast edges, motion direction, and colours. A favourite feature detector among philosophers is the alleged fly detector in the frog. Lettvin et al. (1959) identified cells in the frog retina that responded maximally to small shapes moving across the visual field. The idea that these cells' activity functioned to detect flies rested upon knowledge of the frogs' diet. Using experimental techniques ranging from single-cell recording to sophisticated functional imaging, neuroscientists have recently discovered a host of neurons that are maximally responsive to a variety of stimuli. However, establishing condition (ii) on a feature detector is much more difficult. Even some paradigm examples have been called into question. David Hubel and Torsten Wiesel's (1962) Nobel Prize winning work establishing the receptive fields of neurons in striate cortices are often interpreted as revealing cells whose function is edge detection. However, Lehky and Sejnowski (1988) have challenged this interpretation. They trained an artificial neural network to distinguish the three-dimensional shape and orientation of an object from its two-dimensional shading pattern. Their network incorporates many features of visual neurophysiology. Nodes in the trained network turned out to be maximally responsive to edge contrasts, but did not appear to have the function of edge detection.
Kathleen Akins (1996) offers a different neuro philosophical challenge to informational semantics and its affiliated feature-detection view of sensory representation. We saw in the previous section how Akins argues that the physiology of thermoreceptor violates three necessary conditions on ‘veridical’ representation. From this fact she draws doubts about looking for feature detecting neurons to ground a psychosemantics generally, including thought contents. Human thoughts about flies, for example, are sensitive to numerical distinctions between particular flies and the particular locations they can occupy. But the ends of frog nutrition are well served without a representational system sensitive to such ontological refinements. Whether a fly seen now is numerically identical to one seen a moment ago, need not, and perhaps cannot, figure into the frog's feature detection repertoire. Akins' critique casts doubt on whether details of sensory transduction will scale up to encompass of some adequately unified psychosemantics. It also raises new questions for human intentionality. How do we get from activity patterns in "narcissistic" sensory receptors, keyed not to "objective" environmental features but rather only to effects of the stimuli on the patch of tissue innervated, to the human ontology replete with enduring objects with stable configurations of properties and relations, types and their tokens (as the "fly-thought" example presented above reveals), and the rest? And how did the development of a stable, and rich ontology confer survival advantages to human ancestors?
Consciousness has reemerged as a topic in philosophy of mind and the cognitive and brain sciences over the past three decades. Instead of ignoring it, many physicalists now seek to explain it (Dennett, 1991). Here we focus exclusively on ways those neuroscientific discoveries have impacted philosophical debates about the nature of consciousness and its relation to physical mechanisms. Thomas Nagel argues that conscious experience is subjective, and thus permanently recalcitrant to objective scientific understanding. He invites us to ponder ‘what it is like to be a bat’ and urges the intuition that no amount of physical-scientific knowledge (including neuroscientific) supplies a complete answer. Nagel's intuition pump has generated extensive philosophical discussion. At least two well-known replies make direct appeal to neurophysiology. John Biro suggests that part of the intuition pumped by Nagel, that bat experience is substantially different from human experience, presupposes systematic relations between physiology and phenomenology. Kathleen Akins (1993a) delves deeper into existing knowledge of bat physiology and reports much that is pertinent to Nagel's question. She argues that many of the questions about bat subjectivity that we still consider open hinge on questions that remain unanswered about neuroscientific details. One example of the latter is the function of various cortical activity profiles in the active bat.
More recently philosopher David Chalmers (1996) has argued that any possible brain-process account of consciousness will leave open an ‘explanatory gap’ between the brain process and properties of the conscious experience. This is because no brain-process theory can answer the "hard" question: Why should that particular brain process give rise to conscious experience? We can always imagine ("conceive of") a universe populated by creatures having those brain processes but completely lacking conscious experience. A theory of consciousness requires an explanation of how and why some brain process causes consciousness replete with all the features we commonly experience. The fact that the hard question remains unanswered shows that we will probably never get a complete explanation of consciousness at the level of neural mechanisms. Paul and Patricia Churchland have recently offered the following diagnosis and reply. Chalmers offer a conceptual argument, based on our ability to imagine creatures possessing brains like ours but wholly lacking in conscious experience. But the more one learns about how the brain produces conscious experience-and literature is beginning to emerge (e.g., Gazzaniga, 1995) - the harder it becomes to imagine a universe consisting of creatures with brain processes like ours but lacking consciousness. This is not just to bare assertions. The Churchlands appeal to some neurobiological detail. For example, Paul Churchland (1995) develops a neuroscientific account of consciousness based on recurrent connections between thalamic nuclei (particularly "diffusely projecting" nuclei like the intralaminar nuclei) and the cortex. Churchland argues that the thalamocortical recurrency accounts for the selective features of consciousness, for the effects of short-term memory on conscious experience, for vivid dreaming during REM. (rapid-eye movement) sleep, and other "core" features of conscious experience. In other words, the Churchlands are claiming that when one learns about activity patterns in these recurrent circuits, one can't "imagine" or "conceive of" this activity occurring without these core features of conscious experience. (Other than just mouthing the words, "I am now imagining activity in these circuits without selective attention/the effects of short-term memory/vivid dreaming . . . ")
A second focus of sceptical arguments about a complete neuroscientific explanation of consciousness is sensory qualia: the introspectable qualitative aspects of sensory experience, the features by which subjects discern similarities and differences among their experiences. The colours of visual sensations are a philosopher's favourite example. One famous puzzle about colour qualia is the alleged conceivability of spectral inversions. Many philosophers claim that it is conceptually possible (if perhaps physically impossible) for two humans not to differ neurophysiological, while the Collor that fire engines and tomatoes appear to have to one subject is the Collor that grass and frogs appear to have to the other (and vice versa). A large amount of neuroscientifically-informed philosophy has addressed this question. A related area where neurophilosophical considerations have emerged concerns the metaphysics of colours themselves (rather than Collor experiences). A longstanding philosophical dispute is whether colours are objective property’s Existing external to perceiver or rather identifiable as or dependent upon minds or nervous systems. Some recent work on this problem begins with characteristics of Collor experiences: For example that Collor similarity judgments produce Collor orderings that align on a circle. With this resource, one can seek mappings of phenomenology onto environmental or physiological regularities. Identifying colours with particular frequencies of electromagnetic radiation does not preserve the structure of the hue circle, whereas identifying colours with activity in opponent processing neurons does. Such a tidbit is not decisive for the Collor objectivist-subjectivist debate, but it does convey the type of neurophilosophical work being done on traditional metaphysical issues beyond the philosophy of mind.
We saw in the discussion of Hardcastle (1997) two sections above that Neurophilosophers have entered disputes about the nature and methodological import of pain experiences. Two decades earlier, Dan Dennett (1978) took up the question of whether it is possible to build a computer that feels pain. He compares and notes pressure between neurophysiological discoveries and common sense intuitions about pain experience. He suspects that the incommensurability between scientific and common sense views is due to incoherence in the latter. His attitude is wait-and-see. But foreshadowing Churchland's reply to Chalmers, Dennett favours scientific investigations over conceivability-based philosophical arguments.
Neurological deficits have attracted philosophical interest. For thirty years philosophers have found implications for the unity of the self in experiments with commissurotomy patients. In carefully controlled experiments, commissurotomy patients display two dissociable seats of consciousness. Patricia Churchland scouts philosophical implications of a variety of neurological deficits. One deficit is blindsight. Some patients with lesions to primary visual cortex report being unable to see items in regions of their visual fields, yet perform far better than chance in forced guess trials about stimuli in those regions. A variety of scientific and philosophical interpretations have been offered. Ned Form (1988) worries that many of these conflate distinct notions of consciousness. He labels these notions ‘phenomenal consciousness’ (‘P-consciousness’) and ‘access consciousness’ (‘A-consciousness’). The former is that which, ‘what it is like-ness of experience. The latter is the availability of representational content to self-initiated action and speech. Form argues that P-consciousness is not always representational whereas A-consciousness is. Dennett and Michael Tye are sceptical of non-representational analyses of consciousness in general. They provide accounts of blindsight that do not depend on Form's distinction.
Many other topics are worth neurophilosophical pursuit. We mentioned commissurotomy and the unity of consciousness and the self, which continues to generate discussion. Qualia beyond those of Collor and pain have begun to attract neurophilosophical attention has self-consciousness. The first issues to arise in the ‘philosophy of neuroscience’ (before there was a recognized area) was the localization of cognitive functions to specific neural regions. Although the ‘localization’ approach had dubious origins in the phrenology of Gall and Spurzheim, and was challenged severely by Flourens throughout the early nineteenth century, it reemerged in the study of aphasia by Bouillaud, Auburtin, Broca, and Wernicke. These neurologists made careful studies (where possible) of linguistic deficits in their aphasic patients followed by brain autopsies postmortem. Broca's initial study of twenty-two patients in the mid-nineteenth century confirmed that damage to the left cortical hemisphere was predominant, and that damage to the second and third frontal convolutions was necessary to produce speech production deficits. Although the anatomical coordinates’ Broca postulates for the ‘speech production centres do not correlate exactly with damage producing production deficits, both are that in this area of frontal cortex and speech production deficits still bear his name (‘Broca's area’ and ‘Broca's aphasia’). Less than two decades later Carl Wernicke published evidence for a second language centre. This area is anatomically distinct from Broca's area, and damage to it produced a very different set of aphasic symptoms. The cortical area that still bears his name (‘Wernicke's area’) is located around the first and second convolutions in temporal cortex, and the aphasia that bears his name (‘Wernicke's aphasia’) involves deficits in language comprehension. Wernicke's method, like Broca's, was based on lesion studies: a careful evaluation of the behavioural deficits followed by post mortem examination to find the sites of tissue damage and atrophy. Lesion studies suggesting more precise localization of specific linguistic functions remain a cornerstone to this day in aphasic research
Lesion studies have also produced evidence for the localization of other cognitive functions: for example, sensory processing and certain types of learning and memory. However, localization arguments for these other functions invariably include studies using animal models. With an animal model, one can perform careful behavioural measures in highly controlled settings, then ablate specific areas of neural tissue (or use a variety of other techniques to Form or enhance activity in these areas) and remeasure performance on the same behavioural tests. But since we lack an animal model for (human) language production and comprehension, this additional evidence isn't available to the neurologist or neurolinguist. This fact makes the study of language a paradigm case for evaluating the logic of the lesion/deficit method of inferring functional localization. Philosopher Barbara Von Eckardt (1978) attempts to make explicit the steps of reasoning involved in this common and historically important method. Her analysis begins with Robert Cummins' early analysis of functional explanation, but she extends it into a notion of structurally adequate functional analysis. These analyses break down a complex capacity C into its constituent capacity’s c1, c2, . . . cn, where the constituent capacities are consistent with the underlying structural details of the system. For example, human speech production (complex capacity C) results from formulating a speech intention, then selecting appropriate linguistic representations to capture the content of the speech intention, then formulating the motor commands to produce the appropriate sounds, then communicating these motor commands to the appropriate motor pathways (constituent capacity’s c1, c2, . . . , cn). A functional-localization hypothesis has the form: Brain structure S in an organism (type) O has constituent capacity ci, where ci is a function of some part of O. An example, Brains Broca's area (S) in humans (O) formulates motor commands to produce the appropriate sounds (one of the constituent capacities ci). Such hypotheses specify aspects of the structural realization of a functional-component model. They are part of the theory of the neural realization of the functional model.
Armed with these characterizations, Von Eckardt argues that inference to a functional-localization hypothesis proceeds in two steps. First, a functional deficit in a patient is hypothesized based on the abnormal behaviour the patient exhibits. Second, localization of function in normal brains is inferred on the basis of the functional deficit hypothesis plus the evidence about the site of brain damage. The structurally-adequate functional analysis of the capacity connects the pathological behaviour to the hypothesized functional deficit. This connection suggests four adequacy conditions on a functional deficit hypothesis. First, the pathological behaviour P (e.g., the speech deficits characteristic of Broca's aphasia) must result from failing to exercise some complex capacity C (human speech production). Second, there must be a structurally-adequate functional analysis of how people exercise capacity C that involves some constituent capacity ci (formulating motor commands to produce the appropriate sounds). Third, the operation of the steps described by the structurally-adequate functional analysis minus the operation of the component performing ci (Broca's area) must result in pathological behaviour P. Fourth, there must not be a better available explanation for why the patient does P. Arguments to a functional deficit hypothesis on the basis of pathological behaviour is thus an instance of argument to the best available explanation. When postulating a deficit in a normal functional component provides the best available explanation of the pathological data, we are justified in drawing the inference.
Von Eckardt applies this analysis to a neurological case study involving a controversial reinterpretation of agnosia. Her philosophical explication of this important neurological method reveals that most challenges to localization arguments of whether to argue only against the localization of a particular type of functional capacity or against generalizing from localization of function in one individual to all normal individuals. (She presents examples of each from the neurological literature.) Such challenges do not impugn the validity of standard arguments for functional localization from deficits. It does not follow that such arguments are unproblematic. But they face difficult factual and methodological problems, not logical ones. Furthermore, the analysis of these arguments as involving a type of functional analysis and inference to the best available explanation carries an important implication for the biological study of cognitive function. Functional analyses require functional theories, and structurally adequate functional analyses require checks imposed by the lower level sciences investigating the underlying physical mechanisms. Arguments to best available explanation are often hampered by a lack of theoretical imagination: the available explanations are often severely limited. We must seek theoretical inspiration from any level of theory and explanation. Hence making explicit the ‘logic’ of this common and historically important form of neurological explanation reveals the necessity of joint participation from all scientific levels, from cognitive psychology down to molecular neuroscience. Von Eckardt anticipated what came to be heralded as the ‘co-evolutionary research methodology,’ which remains a centerpiece of neurophilosophy to the present day.
Over the last two decades, evidence for localization of cognitive function has come increasingly from a new source: the development and refinement of neuroimaging techniques. The form of localization-of-function argument appears not to have changed from that employing lesion studies (as analysed by Von Eckardt). Instead, these imaging technologies resolve some of the methodological problems that plage lesion studies. For example, researchers do not need to wait until the patient dies, and in the meantime probably acquires additional brain damage, to find the lesion sites. Two functional imaging techniques are prominent: Positron emission tomography, or PET, and functional magnetic resonance imaging, or MRI. Although these measure different biological markers of functional activity, both now have a resolution down to around 1mm. As these techniques increase spatial and temporal resolution of functional markers and continue to be used with sophisticated behavioural methodologies, the possibility of localizing specific psychological functions to increasingly specific neural regions continues to grow
What we now know about the cellular and molecular mechanisms of neural conductance and transmission is spectacular. The same evaluation holds for all levels of explanation and theory about the mind/brain: maps, networks, systems, and behaviour. This is a natural outcome of increasing scientific specialization. We develop the technology, the experimental techniques, and the theoretical frameworks within specific disciplines to push forward our understanding. Still, a crucial aspect of the total picture gets neglected: the relationship between the levels, the ‘glue’ that binds knowledge of neuron activity to subcellular and molecular mechanisms, network activity patterns to the activity of and connectivity between single neurons, and behaviour to network activity. This problem is especially glaring when we focus on the relationship between ‘cognitivist’ psychological theories, postulating information-bearing representations and processes operating over their contents, and the activity patterns in networks of neurons. Co-evolution between explanatory levels still seems more like a distant dream rather than an operative methodology.
It is here that some neuroscientists appeal to ‘computational’ methods. If we examine the way that computational models function in more developed sciences (like physics), we find the resources of dynamical systems constantly employed. Global effects (such as large-scale meteorological patterns) are explained in terms of the interaction of ‘local’ lower-level physical phenomena, but only by dynamical, nonlinear, and often chaotic sequences and combinations. Addressing the interlocking levels of theory and explanation in the mind/brain using computational resources that have worked to bridge levels in more mature sciences might yield comparable results. This methodology is necessarily interdisciplinary, drawing on resources and researchers from a variety of levels, including higher levels like experimental psychology, ‘program-writing’ and ‘connectionist’ artificial intelligence, and philosophy of science.
However, the use of computational methods in neuroscience is not new. Hodgkin, Huxley, and Katz incorporated values of voltage-dependent potassium conductance they had measured experimentally in the squid giant axon into an equation from physics describing the time evolution of a first-order kinetic process. This equation enabled them to calculate best-fit curves for modelled conductance versus time data that reproduced the S-shaped (sigmoidal) function suggested by their experimental data. Using equations borrowed from physics, Rall (1959) developed the cable model of dendrites. This theory provided an account of how the various inputs from across the dendritic tree interact temporally and spatially to determine the input-output properties of single neurons. It remains influential today, and has been incorporated into the genesis software for programming neurally realistic networks. More recently, David Sparks and his colleagues have shown that a vector-averaging model of activity in neurons of superior colliculi correctly predicts experimental results about the amplitude and direction of saccadic eye movements. Working with a more sophisticated mathematical model, Apostolos Georgopoulos and his colleagues have predicted direction and amplitude of hand and arm movements based on averaged activity of 224 cells in motor cortices. Their predictions have borne out under a variety of experimental tests. We mention these particular studies only because we are familiar with them. We could multiply examples of the fruitful interaction of computational and experimental methods in neuroscience easily by one-hundred-fold. Many of these extend back before ‘computational neuroscience’ was a recognized research endeavour.
We've already seen one example, the vector transformation account, of neural representation and computation, under active development in cognitive neuroscience. Other approaches using ‘cognitivist’ resources are also being pursued. Many of these projects draw upon ‘cognitivist’ characterizations of the phenomena to be explained. Many exploit ‘cognitivist’ experimental techniques and methodologies. Some even attempt to derive ‘cognitivist’ explanations from cell-biological processes (e.g., Hawkins and Kandel 1984). As Stephen Kosslyn puts it, cognitive neuroscientists employ the ‘information processing’ view of the mind characteristic of cognitivism without trying to separate it from theories of brain mechanisms. Such an endeavour calls for an interdisciplinary community willing to communicate the relevant portions of the mountain of detail gathered in individual disciplines with interested nonspecialists: not just people willing to confer with those working at related levels, but researchers trained in the methods and factual details of a variety of levels. This is a daunting requirement, but it does offer some hope for philosophers wishing to contribute to future neuroscience. Thinkers trained in both the ‘synoptic vision’ afforded by philosophy and the factual and experimental basis of genuine graduate-level science would be ideally equipped for this task. Recognition of this potential niche has been slow among graduate programs in philosophy, but there is some hope that a few programs are taking steps to fill it.
In the final analysis there will be philosophers unprepared to accept that, if a given cognitive capacity is psychologically real, then there must be an explanation of how it is possible for an individual in the course of human development to acquire that cognitive capacity, or anything like it, can have a role to play in philosophical accounts of concepts and conceptual abilities. The most obvious basis for such a view would be a FrĂ©gean distrust of “psychology” that leads to a rigid division of labour between philosophy and psychology. The operative thought is that the task of a philosophical theory of concepts is to explain what a given concept is or what a given conceptual ability consist in. This, it is frequently maintained, is something that can be done in complete independence of explaining how such a concept or ability might be acquired. The underlying distinction is one between philosophical questions centring around concept possession and psychological questions centring around concept possibilities for an individual to acquire that ability, then it cannot be psychologically real. Nevertheless, this distinction is, however, strictly one does adhere to the distinction, it provides no support for a rejection of any given cognitive capacity for which is psychologically real. The neo-FrĂ©gean distinction is directly against the view that facts about how concepts are acquired have a role to play in explaining and individualizing concepts. But this view does not have to be disputed by a supporter as such, nonetheless, all that the supporter is to commit is that the principle that no satisfactory account of what a concept is should make it impossible to provide explanation of how that concept can be acquired. That is, that this principle has nothing to say about the further question of whether the psychological explanation has a role to play in a constitutive explanation of the concept, and hence is not in conflict with the neo-FrĂ©gean distinction.
A full account of the structure of consciousness, will need to illustrate those higher, conceptual forms of consciousness to which little attention on such an account will take and about how it might emerge from given points of value, is the thought that an explanation of everything that is distinctive about consciousness will emerge out of an account of what it is for a subject to be capable of thinking about himself. But, to a proper understanding of the complex phenomenon of consciousness. There are no facts about linguistic mastery that will determine or explain what might be termed the cognitive dynamics that are individual processes that have found their way forward for a theory of consciousness, it sees, to chart the characteristic features individualizing the various distinct conceptual forms of consciousness in a way that will provide a taxonomy of unconsciousness and they, to show how these manifest the characterlogical functions a can to determine at the level of content. What is hoped is now clear is that these forms of higher forms of consciousness emerge from a rich foundation of non-conceptual representations of thought, which can only expose and clarify their conviction that these forms of conscious thought hold the key, not just to an eventful account of how mastery of the conscious paradigms, but to a proper understanding of the plexuity of self-consciousness and/or the overall conjecture of consciousness that stands alone as to an everlasting vanquishment into the ever unchangeless state of unconsciousness, and its abysses are only held by hidden and underlying latencies.
Research in neuroscience has shown that language processing is a staggeringly complex phenomenon that places incredible demands on memory and learning. Language functions extend, for example, into all major lobes of the neocortex: Auditory input is associated with the temporal area; tactile input is associated with the parietal area, and attention, working memory, and planning are associated with the frontal cortex of the left or dominant hemisphere. The left prefrontal region is associated with verb and noun production tasks and in the retrieval of words representing action. Broca’s area, adjacent to the mouth-tongue region of motor cortex, is associated with vocalization in word formation, and Wernicke’s area, adjacent to the auditory cortex, is associated with sound analysis in the sequencing of words.
Lower brain regions, like the cerebellum, have also evolved in our species to assist in language processing. Until recently, the cerebellum was thought to be exclusively involved with automatic or preprogrammed movements such as throwing a ball, jumping over a high hurdle or playing well-practiced noted on a musical instrument. Imaging studies in neuroscience indicate, however, that the cerebellum is activated during speaking, and most activated when the subject is making difficult word associations. It is now thought that the cerebellum plays a role in associations by providing access to fairly automatic word sequences and by augmenting rapid shifts in attention.
The midbrain and brain stem, situated on top of the spinal cord, coordinate input and output systems in the head and play a crucial role in communication functions. Vocalization has a special associations with the midbrain, which coordinates the interaction of the oral and respiratory tracks necessary to make speech sounds. Since this vocalization requires synchronous activity among oral, vocal, and respiratory muscles, these functions probably connect to a central site. This site appears to be the central gray area of the brain. The central gray area links the reticular nuclei and brain stem motor nuclei to comprise a distributed network for sound production. And while human speech is dependent on structures in the cerebral cortex as well as on rapid movement of the oral and vocal muscles, this is not true for vocalisation in other mammals.
Most experts agree that our ancestries became capable of fully articulated speech based on complex grammar and syntax between two hundred thousand and some hundred thousand years ago. The mechanisms in the human brain that allowed for this great achievement clearly evolved, however, over great spans of time. In biology textbooks, the list of prior adaptations that enhanced the ability of our ancestors to use language normally includes the following: an increase in intelligence, significant alterations of oral and auditory abilities, the separation or localization of functions to the two sides of the brain, and the evolution of some sort of innate or hard-wired grammar. But when we look at how our ability to use language could have actually evolved over the entire course of hominid evolution, the process seems more basic and more counterintuitive than we had previously imagined.
Although we share some aspects of vocalization with our primate cousins, the mechanisms of human vocalization are quite different and have evolved over great spans of time. Incremental increases in hominid brain size over the last 2.5 million years enhanced cortical control over the larynx, which originally evolved to prevent food and other particles from entering the windpipe or trachea; this eventually contributed to the use of vocal symbolization. Humans have more voluntary motor control over sound produced in the larynx than any other vocal species, and this control is associated with higher brain systems involved in skeletal muscle control as opposed to just visceral control. As a result, humans have direct cortical motor control over phonation and oral movement while chimps do not.
The larynx in modern humans is positioned in a comparatively low position to the throat and significantly increases the range and flexibility of sound production. The low position of the larynx allows greater changes in the volume to the resonant chamber formed by the mouth and pharynx and makes it easier to shift sounds to the mouth and away from the nasal cavity. The dramatic result is that sounds that comprise vowel components of speech become much more variable, including extremes in resonance combinations such as the “ee” sound in “tree” and the “aw” sound in “flaw.” Equally important, the repositioning of the larynx dramatically increases the ability of the mouth and tongue to modify vocal sounds. This shift in the larynx also makes it more likely that food and water passing over the larynx will enter the trachea, and this explains why humans are more inclined to experience choking. Yet this disadvantage, which could have caused the shift to e selected against, was clearly out-weighed by the advantage of being able to produce all the sounds used in modern language systems.
Some have argued that this removal of constraints on vocalization suggest that spoken language based on complex symbol systems emerged quite suddenly in modern humans only about one hundred thousand years ago. It is, however, far more likely that language use began with very primitive symbolic systems and evolved over time to increasingly complex systems. The first symbolic systems were not full-blown language systems, and they were probably not as flexible and complex as the vocal calls and gestural displays of modern primates. It is also probable that the first users of primitive symbolic systems coordinated most of their social comminations with call and display behaviours like those of modern apes and monkeys.
Critically important to the evolution of enhanced language skills is that behavioural adaptions tend to precede and condition biological changes. This represents a reversal of the usual course of evolution where biological change precedes behavioural adaption. When the first hominids began to use stone tools, they probably did si in a very haphazard fashion by drawing on their flexible ape-like learning abilities. But the use of this technology over time opened a new ecological niche where selective pressures occasioned new adaptions. A tool use became more indispensable for obtaining food and organized social behaviours, mutations that enhanced the use of tools probably functioned as a principal source of selection for both bodied and brains.
The fist stone choppers appear in the fossil remnant fragments remaining about 2.5 million years ago, and they appear to have been fabricated with a few sharp blows of stone on stone. It is reasonable to assume that these primitive tools, which were hand-held and probably used to cut flesh and to chip bone to expose the marrow, were created by Homo habilis - the first large-brained hominid. Stone making is obviously a skill passed on from one generation to the next by learning as opposed to a physical trait passed on genetically. After these tools became critical to survival, this introduced selection for learning abilities that did not exist for other species. Although the early tool maskers may have had brains roughly comparable to those of modern apes, they were already in the process of being adapted for symbol learning.
The first symbolic representations were probably associated with social adaptations that were quite fragile, and any support that could reinforce these adaptions I the interest of survival would have been favoured by evolution. The expansion of the forebrain in Homo habilis, particularly the prefrontal cortex, was on of the core adaptations. This adaption was enhanced over time by increased connectivity to brain regions involved in language processing.
It is easy to imagine why incremental improvements in symbolic representations provided a selective advantage. Symbolic communication probably enhanced cooperation in the relationship of mothers to infants, allowed forgoing techniques to be more easily learned, served as the basis for better coordinating scavenging and hunting activities, and generally improved the prospect of attracting a mate. As the list of domains in which symbolic communication was introduced became longer over time, this probably resulted in new selective pressures that served to make this communication more elaborate. After more functions became dependent on this communication, those who failed in symbol learning or could only use symbols awkwardly were less likely to pass on their genes to subsequent generations.
The crude language of the earliest users of symbols must have been replete with gestures and nonsymbiotic vocalizations, and spoken language probably became a reactively independent and closed system only after the emergence of hominids to use symbolic communication evolved, symbolic forms progressively took over functions served by non-vocal symbolic forms. This is reflected in modern languages. The structure of syntax in these languages often reveals its origins in pointing gestures, in the manipulation and exchange of objects, and in more primitive constructions of spatial and temporal relationships. And we still use nonverbal vocalizations and gestures to complement meaning in spoken language.
The general idea is very powerful, however, the relevance of spatiality to self-consciousness comes about not merely because the world is spatial but also because the self-concious subject is a spatial element of the world. One cannot v=be self-conscious without bing aware that one is a spatial element of the world, and one cannot be ware that one is a spatial element of the world without a grasp of the spatial nature of the world. Oppositely, the very idea of a perceivable, objective spatial world brings with it the idea of the subject as being in the wold, with the course of his perceptions due to his changing position in thr world and to the more or less stable way the world is. The idea that there is an objective world and the idea that the subject is somewhere, and where he is given by what he can perceive.
Research, however distant, are those that neuroscience reveals in that the human brain is a massive parallel system which language processing is widely distributed. Computer generated images of human brains engaged in language processing reveal a hierarchal organization consisting of complicated clusters of brain areas that process different component functions in controlled time sequences. And it is now clear that language processing is not accomplished by stand-aline or unitary modules that evolved with the addition of separate modules that were eventually wired together on some neutral circuit board.
While the brain that evolved this capacity was obviously a product of Darwinian evolution, the most critical precondition for the evolution of this brain cannot be simply explained in these terms. Darwinian evolution can explain why the creation of stone tools altered conditions for survival in a new ecological niche in which group living, pair bonding, and more complex social structures were critical to survival. And Darwinian evolution can also explain why selective pressures in this new ecological niche favoured preadaptive changes required for symbolic communication. But as this communication resulted in increasingly more complex behaviours, social evolution began to take precedence over physical evolution in the sense that mutations resulting in enhanced social behaviour became selectively advantageous within the context of the social behaviour of hominids.
Since this communication was based on symbolic vocalization that required the evolution of neural mechanisms and processes that did not evolve in any other species, this marked the emergence of a mental realm that would increasingly appear as separate and distinct from the external material realm.
If the emergent reality in this mental realm cannot be reduced to, or entirely explained in terms of, the sum of its parts, it seems reasonable to conclude that this reality is greater than the sum of its parts. For example, a complete proceeding of the manner in which light in particular wave lengths is proceeding by the human brain to generate a particular colour says nothing about the actual experience of colour. In other words, a complete scientific description of all the mechanisms involved in processing the colour blue does not correspond with the colour blue as perceived in human consciousness. And no scientific description of the physical substrate of a thought or feeling, no matter how complete, ca account for the actualized experience of a thought or feeling as an emergent aspect of global brain function.
If we could, for example, define all of the neural mechanisms involved in generating a particular word symbol, this would reveal nothing about the actual experience of the word symbol as an idea in human consciousness, conversely, the experience of the word symbol as an idea would reveal nothing about the neuronal processes involved. And while one mode of understanding the situation necessarily displaces the other, both are required to achieve a complete understanding of the situation.
Even so, we are to include two aspects of biological reality, finding to a more complex order in biological reality appears to be associated with the emergence of new wholes that ae greater than the orbital parts, and the entire biosphere appears to be of a whole that displays self-regulating behaviour that is greater than the sum of its parts. If, however, the emergence of a symbolic universe based on a complex language system could be viewed as another stage in the evolution of more complicated and complex systems as marked by the appearance of a new profound complementary relationship between parts and wholes. This does not allow us to assume that human consciousness was in any sense preordained or predestined by natural process. But it does make it possible, in philosophical terms at least, to argue that this consciousness is an emergent aspect of the elf-organizing properties of biological life.
Another aspect of the evolution of a brain that allowed us to construct symbolic universes based on complex language system that is particularly relevant for our purposes concerns consciousness of self. Consciousness of self as an independent agency or actor is predicted on a fundamental distinction or dichotomy between this self and the other selves. Self, as it is constructed in human subjective reality, is perceived as having an independent existence and a self-referential character in a mental realm separately distinct from the material realm. It was, the assumed separation between these realms that led Descartes to posit his famous dualism in an effort to understand the nature of consciousness in the mechanistic classical universe.
Based on what we now know about the evolution of human language abilities, however, it seems clear that our real or actualized self is not imprisoned in our minds. It is implicitly a part of the larger whole of biological life, derives its existence from embedded relations to this whole, and constructs its reality as based on evolved mechanisms that exist in all human brains. This suggests that any sense of the “otherness” of selves and world is an illusion that disguises of its own actualization such to find the totality of its relations between the part that is of its own characterized self as related to the temporality of being whole that is biological reality. It can be viewed, of a proper definition of this whole must not only include the evolution of the larger undissectible whole of the cosmos and the unbroken evolution of all life from the first self-replication molecule that was the ancestor of DNA. It should also include the complex interactions between all the parts in biological reality that resulted in emergent self-regulating properties in the whole that sustained the existence of the parts.
Based on complications and complex systems in ordinary language conditioned development has been in description of physical reality and the metaphysical concerns that loom largely in the history of mathematics and that the dialogue between the mega-narratives or frame tales of religion and science was a critical factor in the minds of those who contributed to the first scientific revolution of the seventeenth century. Allowing to the better understudy of how the classical paradigm in physical reality as marked by the result in the stark Cartesian division between mind and world that became one of the most characteristic features of Western thought. This is not, however, another strident and ill-mannered diatribe against our misunderstandings, but drawn upon equivalent self realization and undivided wholeness or predicted characterlogic principles of physical reality and the epistemological foundations of physical theory.
Scientific knowledge is an extension of ordinary language into greater levels of abstraction and precision through reliance upon geometry and numerical relationships. We speculate that the seeds of the scientific imagination were planted in ancient Greece, as opposed to Chinese or Babylonian culture, partly because the social, political, and economic climates in Greece was more open to the pursuit of knowledge with marginal cultural utility. Another important factor was that the special character of Homeric religion allowed the Greeks to invent a conceptual framework that would prove useful in future scientific investigations. But it was only after this inheritance from Greek philosophy was wedded to some essential feature of Judeo-Christian beliefs about the origin of the cosmos that the paradigm for classical physics emerged.
The Greek philosophers we now recognized as the originators scientific thoughts were oraclically mystic who probably perceived their world as replete with spiritual agencies and forces. The Greek religious heritage made it possible for these thinkers to attempt to coordinate diverse physical events within a framework of immaterial and unifying ideas. The fundamental assumption that there is a pervasive, underlying substance out of which everything emerges and into which everything returns is attributed to Thales of Miletos. Thales was apparently led to this conclusion out of the belief that the world was full of gods, and his unifying substance, water, was similarly charged with spiritual presence. Religion in this instance served the interests of science because it allowed the Greek philosophers to view “essences” underlying and unifying physical reality as if they were “substances.”
Nonetheless, the belief that the mind of God as Divine Architect permeates the workings of nature was the guiding principle of the scientific thought of Johannes Kepler. For this reason. Most modern physicists would probably feel some discomfort in reading Kepler’s original manuscripts. Physics and metaphysics, astronomy nd astrology, geometry and theology commingle with an intensity that might offend those who practice science in the modern sense of that word. Physical laws, wrote Kepler, “lie within the power of understanding of the human mind, God wanted us to perceive them when he created us in His image in order that we may take part in His own thoughts . . . Our knowledge of numbers and quantities is the same as that of God’s, at least insofar as we can understand something of it in this mortal life.”
The history of science grandly testifies to the manner in which scientific objectivity results in physical theories that must be assimilated into “customary points of view and forms of perception.” the framers of classical physics derived, like the rest of us, their “customary points of view and forms of perception” from macro-level visualized experience. Thus the descriptive apparatus of visualizable experience came to be reflected in the classical descriptive categories.
A major discontinuity appears, however, as we moved from descriptive apparatus dominated by the character of our visualizable experience to a more complete description of physical reality in relativistic and quantum physics. The actual character of physical reality in modern physics lies largely outside the range of visualizable experience. Einstein, was acutely aware of this discontinuity: “We have forgotten what features of the world of experience caused us to frame pre-scientific concepts, and we have great difficulty in representing the world of experience to ourselves without the spectacles of the old-established conceptual interpretation. There is the further difficulty that our language is compelled to work with words which are inseparably connected with those primitive concepts.”
It is time, for the religious imagination and the religious experience to engage the complementary truths of science in filling that which is silence with meaning. However, this does not mean that those who do not believe in the existence of God or Bering should refrain in any sense for assessing the implications of the new truths of science. Understanding these implications dies not require an ontology and is in no way diminished by the lack of an ontology. And one is free to recognize a basis for a dialogue between science and religion for the same reason that one is free to deny that this basis exists - there is nothing in our current scientific world-view that can prove the existence of God or Being and nothing that legitimate any anthropomorphic conceptions of the nature of God or Being. The question of belief in onology remains what it has always been - a question, and the physical universe on the most basic level remains what has always been - a riddle. And the ultimate answer to the question and the ultimate meaning of the riddle are, and probably always will be, a mater of personal choice and conviction.
Our frame reference work is mostly to incorporate in an abounding set-class affiliation between mind and world, by that lay to some defining features and fundamental preoccupations, for which there is certainly nothing new in the suggestion that contemporary scientific world-view legitimates an alternate conception of the relationship between mind and world. Basically, the essential point of attention is that one of “consciousness” and remains in a certain state of our study.
But at the end of this sometimes arduous journey lay to conclusions that should make the trip very worthwhile. Initiatory comments offer resistance in contemporaneous physics or biology for believing I the stark Cartesian division between mind and world that some have rather aptly described as “the disease of the Western mind.” in addition, let us consider the legacy in Western intellectual life of the stark division between mind and world sanctioned by RenĂ© Descartes.
Descartes, the father of modern philosophy, on the grounds that he made epistemological questions the primary and central questions of the discipline. But this is misleading for several reasons. In the first, Descartes conception of philosophy was very different from our own. The term “philosophy” in the seventeenth century was far more comprehensive than it is today, and embraced the whole of what we nowadays call natural science, including cosmology and physics, as well as subjects like anatomy, optics and medicine. Descartes reputation as a philosopher in his own time was based as much as anything on his contributions in these scientific areas. Secondly, even in those Cartesian writings that are philosophical in the modern academic sense, the e epistemological concerns are rather different from the conceptual and linguistic inquires that characterize present-day theory of knowledge. Descartes saw the need to base his scientific system on secure metaphysical foundations: By “metaphysics” he meant inquires into God and the soul and in general all the first things to be discovered by philosophizing. Yet, he was quick to realize that there was nothing in this view that provided untold benefits between heaven and earth and united the universe in a shared and communicable frame of knowledge, it presented us with a view of physical reality that was totally alien from the world of everyday life. Even so, there was nothing in this view of nature that could explain or provide a foundation for the mental, or for all that of direct experience as distinctly human, with no ups, downs or any which ways of direction.
Following these fundamental inquires that include questions about knowledge and certainty, but even here, Descartes is not primarily concerned with the criteria for knowledge claims, or with definitions of the epistemic concepts involved, as his aim is to provide a unified framework for understanding the universe. And with this, Descartes was convinced that the immaterial essences that gave form and structure to this universe were coded in geometrical and mathematical ideas, and this insight led him to invented algebraic geometry.
A scientific understanding to these ideas could be derived, said Descartes, with the aid of precise deduction, and he also claimed that the contours of physical reality could be laid out in three-dimensional coordinates. Following the publication of Isaac Newton’s “Principia Mathematica” in 1687, reductionism and mathematical modelling became the most powerful tools of modern science. And the dream that the entire physical world could be known and mastered through the extension and refinement of mathematical theory became the central feature and guiding principle of scientific knowledge.
The radical separation between mind and nature formalized by Descartes served over time to allow scientists to concentrate on developing mathematical descriptions of matter as pure mechanisms in the absence of any concerns about its spiritual dimension or ontological foundations. Meanwhile, attempts to rationalize, reconcile, or eliminate Descartes’s stark division between mind and matter became perhaps the most central feature of Western intellectual life.
As in the view of the relationship between mind and world sanctioned by classical physics and formalized by Descartes became a central preoccupation in Western intellectual life. And the tragedy of the Western mind is that we have lived since the seventeenth century with the prospect that the inner world of human consciousness and the outer world of physical reality are separated by an abyss or a void that cannot be bridged or in agreement with reconciliation.
In classical physics, external reality consisted of inert and inanimate matte moving in accordance with wholly deterministic natural laws, and collections of discrete atomized parts constituted wholes. Classical physics was also premised, however, a dualistic conception of reality as consisting of abstract disembodied ideas existing in a domain separate from and superior to sensible objects and movements. The notion that the material world experienced by the senses was inferior to the immaterial world experienced by mind or spirit has been blamed for frustrating the progress of physics up to at least the time of Galileo. But in one very important respect, it also made the first scientific revolution possible. Copernicus, Galileo, Kepler. And Newton firmly believed that the immaterial geometrical and mathematical ideas that inform physical reality had a prior existence in the mind of God and that doing physics was a form of communion with these ideas.
The tragedy of the Western mind is a direct consequence of the stark Cartesian division between mind and world. This is the tragedy of the modern mind which “solved the riddle of the universe,” but only to replace it by another riddle: The riddle of itself. Yet, we discover the “certain principles of physical reality,” said Descartes, “not by the prejudices of the senses, but by the light of reason, and which thus possess so great evidence that we cannot doubt of their truth.” Since the real, or that which actually exists external to ourselves, was in his view only that which could be represented in the quantitative terms of mathematics, Descartes concluded that all qualitative aspects of reality could be traced to the deceitfulness of the senses.
Given that Descartes distrusted the information from the senses to the point of doubting the perceived results of repeatable scientific experiments, how did he conclude that our knowledge of the mathematical ideas residing only in mind or I human subjectivity was accurate, much less the absolute truth? He did so by making a leap of faith - God constructed the world, said Descartes, in accordance with the mathematical ideas that our minds are capable of uncovering in their pristine essence. The truths of classical physics as Descartes viewed them were quite literally “revealed” truths, and it was this seventeenth-century metaphysical presupposition that became in the history of science what is termed as the “hidden ontology of classical epistemology.” Descartes lingers in the widespread conviction that science does not provide a “place for man” or for all that we know as distinctly human in subjective reality.
The historical notion in the unity of consciousness has had an interesting history in philosophy and psychology. Taking Descartes to be the first major philosopher of the modern period, the unity of consciousness was central to the study of the mind for the whole of the modern period until the 20th century. The notion figured centrally in the work of Descartes, Leibniz, Hume, Reid, Kant, Brennan, James, and, in most of the major precursors of contemporary philosophy of mind and cognitive psychology. It played a particularly important role in Kant's work.
A couple of examples will illustrate the role that the notion of the unity of consciousness played in this long literature. Consider a classical argument for dualism (the view that the mind is not the body, indeed is not made out of matter at all). It starts like this: When I consider the mind, which is to say of myself, insofar as I am only a thinking thing, I cannot distinguish in myself any parts, but apprehend myself to be clearly one and entire.
Descartes then asserts that if the mind is not made up of parts, it cannot consist of matter, presumably because, as he saw it, anything material has parts. He then goes on to say that this would be enough to prove dualism by itself, had he not already proved it elsewhere. Notice where it is that I cannot distinguish any parts. It is in the unified consciousness that I have of myself.
Here is another, more elaborate argument based on unified consciousness. The conclusion will be that any system of components could never achieve unified consciousness acting in concert. William James' well-known version of the argument starts as follows: Take a sentence of a dozen words, take twelve men, and to each word. Then stand the men in a row or jam them in a bunch, and let each think of his word as intently as he will; nowhere will there be a consciousness of the whole sentence.
James generalizes this observation to all conscious states. To get dualism out of this, we need to add a premise: that if the mind were made out of matter, conscious states would have to be distributed over some group of components in some relevant way. Nevertheless, this thought experiment is meant to show, conscious states cannot be so distributed. Therefore, the conscious mind is not made out of matter. Calling the argument that James is using here the Unity Argument. Clearly, the idea that our consciousness of, here, the parts of a sentence are unified is at the centre of the Unity Argument. Like the first, this argument goes all the way back to Descartes. Versions of it can be found in thinkers otherwise as different from one another as Leibniz, Reid, and James. The Unity Argument continued to be influential into the 20th century. That the argument was considered a powerful reason for concluding that the mind is not the body is illustrated in a backhanded way by Kant's treatment of it (as he found it in Descartes and Leibniz, not James, of course).
Kant did not think that we could demonstrate anything about the nature of the mind, including whether nor is it made out of matter. To make the case for this view, he had to show that all existing arguments that the mind is not material do not work and he set out to do just this in the chapter in the Critique of Pure Reason on the Paralogisms of Pure Reason (1781) (paralogisms are faulty inferences about the nature of the mind). The Unity Argument is the target of a major part of that chapter; if one is going to show that we cannot know what the mind is like, we must dispose of the Unity Argument, which purports to show that the mind is not made out of matter. Kant's argument that the Unity Argument does not support dualism is simple. He urges that the idea of unified consciousness being achieved by something that has no parts or components is no less mysterious than its being achieved by a system of components acting together. Remarkably enough, though no philosopher has ever met this challenge of Kant's and no account exists of what an immaterial mind not made out of parts might be like, philosophers continued to rely on the Unity Argument until well into the 20th century. It may be a bit difficult for us to capture this now but the idea any system of components, and for an even stronger reason might not realize that merge with consciousness, that each system of material components, had a strong intuitive appeal for a long time.
The notion that consciousness agrees to unification and was in addition central to one of Kant's own famous arguments, his ‘transcendental deduction of the categories’. In this argument, boiled down to its essentials, Kant claims that to tie various objects of experience together into a single unified conscious representation of the world, something that he simply assumed that we could do, we could probably apply certain concepts to the items in question. In particular we have to apply concepts from each of four fundamental categories of concept: Quantitative, qualitative, relational, and what he called ‘modal’ concepts. Modal concept’s concern of whether an item might exist, does exist, or must exist. Thus, the four kinds of concept are concepts for how many units, what features, what relations to other objects, and what existence status is represented in an experience.
It was relational conceptual representation that most interested Kant and of relational concepts, he thought the concept of cause-and-effect to be by far the most important. Kant wanted to show that natural science (which for him meant primarily physics) was genuine knowledge (he thought that Hume's sceptical treatment of cause and effect relations challenged this status). He believed that if he could prove that we must tie items in our experience together causally if we are to have a unified awareness of them, he would have put physics back on "the secure path of a science.” The details of his argument have exercised philosophers for more than two hundred years. We will not go into them here, but the argument illustrates how central the notion of the unity of consciousness was in Kant's thinking about the mind and its relation to the world.
Although the unity of consciousness had been at the centre of pre-20th century research on the mind, early in the 20th century the notion almost disappeared. Logical atomism in philosophy and behaviourism in psychology were both unsympathetic to the notion. Logical atomism focussed on the atomic elements of cognition (sense data, simple propositional judgments, etc.), rather than on how these elements are tied together to form a mind. Behaviourism urged that we focus on behaviour, the mind being alternatively myth or something otherwise that we cannot and do not need of studying the mysteriousness of science, from which brings meaning and purpose to humanity. This attitude extended to consciousness, of course. The philosopher Daniel Dennett summarizes the attitude prevalent at the time this way: Consciousness may be the last bastion of occult properties, epiphenomena, immeasurable subjective states - in short, the one area of mind best left to the philosophers. Let them make fools of themselves trying to corral the quicksilver of ‘phenomenology’ into a respectable theory.
The unity of consciousness next became an object of serious attention in analytic philosophy only as late as the 1960s. In the years since, new work has appeared regularly. The accumulated literature is still not massive but the unity of consciousness has again become an object of serious study. Before we examine the more recent work, we need to explicate the notion in more detail than we have done so far and introduce some empirical findings. Both are required to understand recent work on the issue.
To expand on our earlier notion of the unity of consciousness, we need to introduce a pair of distinctions. Current works on consciousness labours under a huge, confusing terminology. Different theorists talk about excess consciousness, phenomenal consciousness, self-consciousness, simple consciousness, creature consciousness, states consciousness, monitoring consciousness, awareness as equated with consciousness, awareness distinguished from consciousness, higher orders thought, higher orders experience, qualia, the felt qualities of representations, consciousness as displaced perception, . . . and on and on and on. We can ignore most of this profusion but we do need two distinctions: between consciousness of objects and consciousness of our representations of objects, and between consciousness of representations and consciousness of self.
It is very natural to think of self-consciousness or, cognitive state more accurately, as a set of cognitive states. Self-knowledge is an example of such a cognitive state. There are plenty of things I know bout self. I know the sort of thing I am: a human being, a warm-blooded rational animal with two legs. I know of many properties and much of what is happening to me, a t both physical and mental levels. I also know things about my past, things I have done and paces I have been as well as people I have me t. but I have many self-conscious cognitive states that are not instances of knowledge. For example, I have the capacity to make plans for the future - to weigh up possible courses of action in the light of goals, desires, and ambitions. I am capable of ca certain type of moral reflection, tide to moral self-and understanding and moral self-evaluation. I can pursue e questions like, what sort of person I am? Am I the sort of person I want to be? Am I the sort of person that I ought to be? This is my ability to think about myself. Of course, much of what I think when I think about myself in these self-conscious ways is also available to me to employing in my thought about other people and other objects.
When I say that I am a self-conscious creature, I am saying that I can do all of these things. But what do they have in common? Could I lack some and still be self-conscious? These are central questions that take us to the heart of many issues in metaphysics, the philosophy of mind, and the philosophy of psychology.
Even so, with the range of putatively self-conscious cognitive states, one might naturally assume that there is a single ability that all presuppose. This is my ability to think about myself. I can only have knowledge about myself if I have beliefs about myself, and I can only have beliefs about myself if I can entertain thoughts about myself. Th e same can be said for autobiographical memories and moral self-understanding.
The proposing account would be on par with other noted examples of the deflationary account of self-consciousness. If, in at all, a straightforward explanation to what makes those of the “self contents” immune to error through misidentification with reference to the semantics of self, then it seems fair to say that the problem of self-consciousness has been dissolved, at least as much as solved.
This proposed account would be on a par with other noted examples as such as the redundancy theory of truth. That is to say, the redundancy theory or the deflationary view of truth claims that the predicate ’ . . . true’ does not have a sense, i.e., expresses no substantive or profound or explanatory concept that ought to be the topic of philosophic enquiry. The approaches admits of different versions, but centres on the pints (1) that ‘it is true that p’ says no more nor less than ‘p’ (hence, redundancy”. (2) that in less direct context, such as ‘everything he said was true’, or ‘all logical consequences of true propositions as true’, the predicated functions as a device enabling us to generalize rather than as an adjective or predicate describing the things he said, or the kinds of proposition that follow from true propositions. For example, translates as ‘(∀p, Q)(P & p ➞ q ➞ q)’ where there is no use of a notion of truth.
There are technical problems in interpreting all uses of the notion of truth in such ways, but they are not generally felt to be insurmountable. The approach needs to explain away apparently substantive uses of the notion, such as . . . ‘science aims at the truth’ or ‘truth is a norm governing discourse. Indeed, postmodernist writing frequently advocates that we must abandon such norms, along with a discredited ‘objective’ concept ion of truth. But perhaps, we can have the norms even when objectivity is problematic, since they can be framed within mention of truth: Science wants to be so that whenever science holds that ‘p’, when ‘p’‘. Discourse is to be regulated by the principle that it is wrong to assert ‘p’. When not-p.
Meanwhile, it seems natural to combine this close connection with conclusions by proposing an account of self-consciousness, in terms of the capacity to think “I”-thoughts that are immune to error through misidentification, though misidentification is a function of the semantics of the “self” - this would be a redundant account of self-consciousness. Once we have an account of what it is to be capable of thinking ‘I- thoughts, we will have explained everything distinctive about self-consciousness. It stems from the thought that what is distinctive about ‘I”-thoughts is that they are either themselves immune to error or they rest on further ‘I’
thoughts that are immune in that way.
Once we have an account of what it is to be capable of thinking thoughts that are immune to error through misidentification, we will have explained everything about thr capacity to think ‘I’-thoughts. As it would to claim of deriving from the thought that immunity to error through misidentification is a function of the semantics of “self-ness.
Once, again, that when we have an account of the semantics of “self-ness” we will have explained everything distinctive about the capacity to think thoughts that are immune to error through misidentification.
The suggestion is that the semantics of “self-ness” will explain what is distinctive about the capacity to think thoughts immune to error through misidentification. Semantics alone cannot be expected to explain the capacity for thinking thoughts. The point in fact, that all that there is to the capacity of think thoughts that are immune tp error is the capacity to think the sort of thought whose natural linguistic expression involves the “self”, where this capacity is given by mastery of the semantics of “self-ness.” Yielding, to explain what it is to master the semantics of “self-ness”, especially to think thoughts immune to error through misidentification.
So on this view, mastery of the semantics of “self-ness” is the single most important explanation in a theory of “self-consciousness.”
Its quickened reformulation might be put to a defender of “redundancy” or the deflationary theory is how mastery of the semantics of “self-ness” can make sense of the distinction between “self-ness contents” that are immune to error through misidentification and the “self contents” that lack such immunity. However, this is only an apparent difficulty when one remembers that those of “selves” content are immune to error through misidentification (those employing ‘”I” as object) have to be broken down into their component elements, as the identification component and the predication components. It is that if identification components of each of such judgements that mastery of the semantics of “self-ness content” is being called upon to explain, and identification component is, of course, immune to error through misidentification.
It is also important to stress how the redundancy and the deflationary theory of self-consciousness, and any theory of self-consciousness that accords a serious role in self-consciousness to mastery of the semantics of the “self-ness”, is motivated by an important principle that has governed much of the development of analytical philosophy . This is the principle that the philosophical analysis of thought can only proceed thought, the philosophical analysis of language such that we communicate thoughts by means of language because we have ab implicit understandings of the workings of language, that is, of the principle governing the use of language: It is these principles, which relate to what is open to view ad mind other that via the medium of language, which endow our sentences with the senses that they carry. In order to analyse thought, therefore, it is necessary to make explicit those principles, regulating our use of language, which we already y implicitly grasp.
Still, at the core of the notion of broad self-consciousness is the recognition of what consciousness is the recognition of what developmental psychologist’s call “self-world dualism.” Any subject properly described as self-conscious must be able to register the distinction between himself and the world, of course, this is a distinction that can be registered in a variety of different way. The capacity for self-ascription of thoughts and experiences, in combination with the capacity to conceptualize the world as a spatial and causally structured system of mind-independent objects, is a high-level way of registering of this distinction.
Consciousness of objects is closely related to sentience and to being awake. It is (at least) being in somewhat of a distinct informational and behavioural intention where its responsive state is for one's condition as played within the immediateness of environmental surroundings. It is the ability, for example, to process and act responsively to information about food, friends, foes, and other items of relevance. One finds consciousness of objects in creatures much less complex than human beings. It is what we (at any rate first and primarily) have in mind when we say of some person or animal as it is coming out of a general anaesthesia, ‘It is regaining consciousness’. Consciousness of objects is not just any form of informational access to the world. It is knowing about, being conscious of, things in the world. We will return to this point in a moment.
We are conscious of our representations when we are conscious, not (just) of some object, but of our representations: ‘I am seeing [as opposed to touching, smelling, tasting] and seeing clearly [as opposed too dimly].’ Consciousness of our own representations it is the ability to process and act responsively to information about one-self, but it is not just any form of such informational access. It is knowing about, being conscious of, one's own psychological states. In Nagel's famous phrase (1974), when we are conscious of our representations, it is ‘like something’ to have them. If, that which seems likely, there are forms of consciousness that do not involve consciousness of objects, they might consist in consciousness of representations, though some theorists would insist that this kind of consciousness is not of representations either (via representations, perhaps, but not of them).
The distinction just drawn between consciousness of objects and consciousness of our representations of objects may seem similar to Block's (1995) well-known distinction between P- [phenomenal] and A- [access] consciousness. Here is his definition of ‘A-consciousness’: "A state is A-conscious if it is poised for direct control of thought and action." He tells us that he cannot define ‘P-consciousness’ in any "remotely noncircular way" but will use it to refer to what he calls "experiential properties,” what it is like to have certain states. Our consciousness of objects may appear to be like Block's A-consciousness. It is not. It is a form of P-consciousness. Consciousness of an object is - how else can we put it? - consciousness of the object. Even if consciousness just is informational excess of a certain kind (something that Block would deny), it is not all form of informational access and we are talking about conscious access here. Recall the idea that it is like something to have a conscious state. Other closely related ideas are that in a conscious state, something appears to one, that conscious states have a ‘felt quality’. A term for all this is phenomenology: conscious states have a phenomenology. (Thus some philosophers speak of phenomenal consciousness here.) We could now state the point we are trying to make this way. If I am conscious of an object, then it is like something to have that object as the content of a representation.
Some theorists would insist that this last statement be qualified. While such a representation of an object may provide everything that a representation has to have for its contents to be like something to me, they would urge, something more is needed. Different theorists would add different elements. For some, I would have to be aware, not just of the object, but of my representation of it. For others, I would have directorial implications that infer of the certain attentive considerations to its way or something other than is elsewhere. We cannot go into this controversy here. Here we are merely making the point that consciousness of objects is more than Block's A-consciousness.
Consciousness of self involves, not just consciousness of states that it is like something to have, but consciousness of the thing that has them, i.e., of ones-self. It is the ability to process and act responsively to information about one-self, but again it is more than that. It is knowing about, being conscious of, one-self, indeed of itself as one-self. Consciousness of one-self in this way is often called consciousness of one-self as the subject of experience. Consciousness of one-self as one-self seems to require an indexical ability and by preference to a special indexical ability at that, not just an ability to pick out something out but to pick something out as one-self. Human beings have such self-referential indexical ability. Whether any other creatures have, it is controversial. The leading nonhuman candidate would be chimpanzees and other primates whom they have taught enough language to use first-person pronouns.
The literature on consciousness sometimes fails to distinguish consciousness of objects, consciousness of one's own representations, and consciousness of self, or treat one three, usually consciousness of one's own representations, as actualized of its owing totality in consciousness. (Conscious states do not have objects, yet is not consciousness of a representation either. We cannot pursue that complication here.) The term ‘conscious’ and cognates are ambiguous in everyday English. We speak of someone regaining consciousness - where we mean simple consciousness of the world. Yet we also say things like, ‘She wasn't conscious of what motivated her to say that’ - where we do not mean that she lacked either consciousness of the world or consciousness of self but rather than she was not conscious of certain things about herself, specifically, certain of her own representational states. To understand the unity of consciousness, making these distinctions is important. The reason is this: the unity of consciousness takes a different form in consciousness of self than it takes in either consciousness of one's own representations or consciousness of objects.
So what is unified consciousness? As we said, the predominant form of the unity of consciousness is being aware of several things at the same time. Intuitively, this is the notion of several representations being aspects of a single encompassing conscious state. A more informative idea can be gleaned from the way philosophers have written about unified consciousness. As emerges from what they have said, the central feature of unified consciousness is taken to be something like this Unity of consciousness: A group of representational relations related to each other that to be conscious of any of them is to be conscious of others of them and of the group of them as a single group.
Call this notion (x). Now, unified consciousness of some sort can be found in all three of the kinds of consciousness we delineated. (It can be found in a fourth, too, as we will see in a moment.) We can have unified consciousness of: Objectively represented to us; the representations themselves; and one-self, the thing having the representations. In the first case, the represented objects would appear as aspects of a single encompassing conscious states. In the second case, the representations themselves would thus appear. In the third case, one is aware of one-self as a single, unified subject. Does (x) fit all three (or all four, including the fourth yet to be introduced)? It does not. At most, it fits the first two. Let us see how this unfolds.
. . . Unified consciousness of objects is the consciousness that one has of the world around one (including one's own body) as aspects of a single world, of the various items in it as linked to other items in it. What makes it unified can be illustrated by an example. Suppose that I am aware of the computer screen in front of me and of the car sitting in my driveway. If awareness of these two items is not unified, I will lack the ability to compare the two. If I cannot bring the car as I am aware of it to the state in which I am aware of the computer screen, I could not answer questions such as, Is the car the same colour as the WordPerfect icon? Or even, As I am experiencing them, is the car to the left or to the right of the computer screen? We can compare represented items in these ways only if we are aware of both items together, as parts of the same field or state or act of conscious. That is what unified consciousness doe for us. (x) fits this kind of unified consciousness well. There are a couple of disorders of consciousness in which this unity seems to break down or be missing. We will examine them shortly.
Unified consciousness of one's own representations is the consciousness that we have of our representations, consciousness of our own psychological states. The representations by which we are conscious of the world are particularly important but, if those theorists who maintain that there are forms of consciousness that does not have objects are right, they are not the only ones. What makes consciousness of our representations unified? We are aware of many representations together, so that they appear as aspects of a single state of consciousness. As with unified consciousness of the world, here to we can compare items of which we have unified consciousness. For example, we can compare what it is like to see an object to what it is like to touch the same object. Thus, (x) fits this kind of unified consciousness well, too.
When one has unified consciousness of self, one is aware of one-self not just as the subject but, in Kant's words, the ‘single common subject’ of many representations and the single common agent of various acts of deliberation and action.
This is one of the two forms of unified consciousness that (x) does not fit. When one is aware of one-self as the common subject of experiences, the common agent of actions, one is not aware of several objects. Some think that when one is aware of one-self as subject, one is not aware of one-self as an object at all. Kant believed this. Whatever the merits of this view, when one is clearly aware of one-self as the single common subject of many representations, one is not aware of several things. As an alternative, one is aware of, and knows that one is aware of, the same thing - via many representations. Call this kind of unified consciousness (Y). Although (Y) is different from (x), we still have the core idea: Unified consciousness consists in tying what is contained in several representations, here most representations of one-self, together so that they are all part of a single field or state or act of consciousness.
Unified consciousness of self has been argued to have some very special properties. In particular, there is a small but important literature on the idea that the reference to one-self as one-self by which one achieves awareness of one-self as subject involves no ‘identification.’ Generalizing the notion a bit, some claim that reference to self does not proceed by way of attribution of properties or features to one-self at all. One argument for this view is that one is or could be aware of one-self as the subject of each of one's conscious experiences. If so, awareness of self is not what Bennett call ‘experience-dividing’ - statements expressing it have "no direct implications of the form ‘I shall experience C rather than D.” If this is so, the linguistic activities using first person pronouns by which we call ourselves subject and the representational states that result have to have some unusual properties.
Finally, we need to distinguish a fourth site of unified consciousness. Let us call it unity of focus. Unity of focus is our ability to pay unified attention to objects, one's representations, and one's own self. It is different from the other sorts of unified consciousness. In the other three situations, consciousness ranges over many alternate objects or many instances of consciousness of an object (in unified consciousness of one’s self). Unity of focus picks out one such item (or a small numbers of them). Wundt captures what I have in mind well in his distinction between the field of consciousness and the focus of consciousness. The consciousness of a single item on which one is focussing is unified because one is aware of many aspects of the item in one state or act of consciousness (especially relational aspects, e.g., any dangers it poses, how it relates to one's goals, etc.) and one is aware of many different considerations with respect to it in one state or act of consciousness (goals, how well one is achieving them with respect to this object, etc.). (x) does not fit this kind of unified consciousness any better than it fit unified consciousness of self? Here to we are not, or need not be, aware of most items. Instead, one is integrating most properties of an item, especially properties that involve relationships to one-self, and integrating most of one's abilities and applying them to the item, and so on. Call this form of unified consciousness (z). One way to think of the affinity of (z) (unified focus) to (x) and (Y) is this. (z) occurs within (x) and (Y) - within unified consciousness of world and self.
Though this has often been overlooked, all forms of unified consciousness come in both simultaneous and across-time versions. That is to say, the unity can consist in links of certain kinds among phenomena occurring at the same time (synchronically) and it can consist in links of certain kinds among phenomena occurring at different times (diachronically). In its synchronic form, it consists in such things as our ability to compare items to one of another, for example, to see if an item fits into another item. Diachronically, it consists in a certain crucial form of memory, namely, our ability to retain a representation of an earlier object in the right way and for long enough to bring it as recalled into current consciousness of currently represented objects in the same as we do with simultaneously represented objects. Though this process across time has always been called the unity of consciousness, sometimes even to the exclusion of the synchronic unity just delineated, another good name for it would be continuity of consciousness. Note that this process of relating earlier to current items in consciousness is more than, and perhaps different from, the learning of new skills and associations. Even severe amnesiacs can do the latter.
That consciousness can be unified across time and at given time points merited of how central unity of consciousness is to cognition. Without the ability to retain representations of earlier objects and unite them with current represented objects, most complex cognition would simply be impossible. The only bits of language that one could probably understand, for example, would be single words; the simplest of sentences is an entity spread over time. Now, unification in consciousness might not be the only way to unite earlier cognitive states (earlier thoughts, earlier experiences) with current ones but it is a central way and the one best known to us. The unity of consciousness is central to cognition.
Justly as thoughts differ from all else that is said to be among the content of the mind in being wholly communicable, it is of the essence of thought that I can convey to you the very thought that I have, as opposed to being able to tell you merely something about what my thought is like. It is of the essence of thought not merely to be communicable, but to be communicable, without excess, by means of language. In order to understand thought, it is necessary, therefore, to understand the means by which thought is expressed.
We communicate thoughts by means of language because we have an implicit understanding of the workings of language, that is, of the principles governing the use of language, it is these principles, which relate to what is open to view in the employment of language, unaided by any supposed contact between mind and mind other than via the medium of language, which endow our sentences with the senses that they carry. In order to analyses thought, therefore, it is necessary to make explicit those principles, regulating our use of language, which we already implicitly grasp.
By noting that (x), (y) and (z) are not the only kinds of mental unity. Our remarks about (z), specifically about what can be integrated in focal attention, might already have suggested as much. There is unity in the exercise of our cognitive capacities, unity that consists of integration of motivating factors, perceptions, beliefs, etc., and there is unity in the outputs, unity that consists of integration of behaviour.
Human beings bring a strikingly wide range of factors to bear on a cognitive task such as seeking to characterize something or trying to decide what to do about something. For example, we can bring to bear of what we want, and what we believe, and also of our attitudinal values for which we can of our own self, situation, and context, allotted from each of our various senses: Its continuing causality in the information about the situation, other people, others' beliefs, desires, attitudes, etc.; the resources of however many languages we have possession in the availabilities for us; many-sided kinds of memory; bodily sensations; our various and very diverse problem-solving skills; and so on. Not only can we bring all these elements to bear, we can integrate them in a way that is highly structured and ingeniously appropriate to our goals and the situation(s) before us. This form of mental unity could appropriately be called unity of cognition. Unity of consciousness often goes with unity of cognition because one of our means of unifying cognition with respect to some object or situation is to focus on it consciously. However, there is at least some measure of unified cognition in many situations of which we are not conscious, as is testified by our ability to balance, control our posture, manoeuver around obstacles while our consciousness is entirely absorbed with something else, and so on.
At the other end of the cognitive process, we find an equally interesting form of unity, what we might call unity of behaviour, our ability to correlate our limbs, eyes, bodily attitude, etc. The precision and complexity of the behavioural coordination we can achieve would be difficult to exaggerate. Think of a concert pianist performing the complicated work.
One of the most interesting ways to study psychological phenomena is to see what happens when they or related phenomena break down. Phenomena that look simple and seamless when functioning smoothly often turn out to have all sorts of structure when they begin to malfunction. Like other psychological phenomena, we would expect unified consciousness to be open to being damaged, distorted, etc., too. If the unity of consciousness is as important to cognitive functioning as we have been suggesting, such damage or distortion should create serious problems for the people to whom it happens. The unity of consciousness is damaged and distorted in both naturally-occurring and experimental situations. Some of these situations are indeed very serious for those undergoing them.
In fact, unified consciousness can break down in what look to be two distinct ways. There are situations in which saying that one unified conscious being has split into two unified conscious beings without the unity itself being destroyed is natural or even significantly damaged, and situations in which always we have one being with one instance of consciousness. However, the unity itself may be damaged or even destroyed. In the former cases, there is reason to think that a single instance of unified consciousness has become two (or something like two). In the latter cases, unity of consciousness has been compromised in some way but nothing suggests that anything has split.
First, situations in which we are inclined to say that something has split. Scrambling description seems natural in at least three different kinds of situations.
One is ‘brain bisection’ operation (commissurotomies), specifically certain results of them. In these operations, the corpus callosum is cut to stop the spread of epileptic seizures from one hemisphere to the other. The corpus callosum is a large strand of about 200,000,000 neurons running from one hemisphere to the other. When present, it is the chief channel of communication between the hemispheres. These operations, done mainly in the 1960s, were a last-ditch efforts to control certain kinds of severe epilepsy by stopping seizures in one lobe of the cerebral cortex from spreading to the other lobe. Under certain laboratory conditions, two ‘centres of consciousness’ seem to appear in patients who have had this operation. Here is a couple of examples of the kinds of behaviour that prompt such an assessment.
The human retina is split vertically so that the left half the retina is primarily hooked up to the left hemisphere of the brain and the right half the retina is hooded up to the right hemisphere of the brain. Now suppose that we flash the word TAXABLE on a screen in front of a brain bisected patient so that the letters TAX hit one side of the retina, the letters ABLE the other and we put measures in place to ensure that the information hitting each retina stays in one lobe and is not fed to the other. If such a patient is asked what word is being shown, the mouth will say TAX while the hand control condition by the hemisphere that does not control the mouth (usually the left hand) will write ABLE. Or, if the hemisphere that controls a hand is asked to do arithmetic in a way that does not penetrate to the hemisphere that controls the mouth and the hands are shielded from the eyes, the mouth will insist that it is not doing arithmetic, has not even thought of arithmetic today, etc., - while the appropriate hand is busily doing arithmetic! Notice that since the two ‘centres’ coexist and are active at the same time, whatever breach of unified consciousness there is in these cases is a breach of synchronically unified consciousness. These operations have received a huge amount of attention from philosophers in the past few decades and we will return to them.
Another phenomenon where we may find something like a split without diminished or destroyed unity is hemi-neglect, the strange phenomenon of losing all sense of one side of one's body or sometimes a part of one side of the body. Whatever it is exactly that is going on in hemi-neglect, unified consciousness remains. It is just that its ‘range’ has been bizarrely circumscribed. It ranges over only half the body (in the most common situation), not seamlessly over the whole body. Where we expect proprioception and perception of the whole body, in these patients they are of (usually) only one-half of the body.
A third candidate phenomenon is what used to be called Multiple Personality Disorder, now, more neutrally, Dissociative Identity Disorder (DID), everything about this phenomenon is controversial, including whether there is any real multiplicity of consciousness at all, but one common way of describing what is going on in at least some central cases is to say that the units (whether we call them persons, personalities, sides of a single personality, or whatever) ‘take turns’, usually with pronounced changes in personality. When one is active, the other(s) usually is(are) not. If this is an accurate description, then here to we have a breach in unity of some kind in which unity is nevertheless not destroyed. Notice that whereas in brain bisection cases the breach, whatever it is like, is synchronic (at a time), here it is diachronic (across time), different unified ‘package’ of consciousness taking turns. The breach consists primarily in some pattern of reciprocal (or sometimes one way) amnesia - some pattern of each ‘package’ not remembering having the experiences or doing the things had or done when another ‘package’ was in charge.
By contrast to brain bisection and DID cases, there are phenomena in which unified consciousness does not seem to split and does seem to be damaged or even destroyed together. In brain bisection and dissociative identity cases, the most that is happening is that unified consciousness is splitting into two or more proportionally intact units - two or more at a time or two or more across time. It is a matter of controversy whether even that is happening, especially in DID cases, but we clearly do not have more than that. In particular, the unity itself does not disappear; although it may split, we could say, it does not shatter. There are at least three kinds of case in which unity does appear to shatter.
One is some particularly severe form of schizophrenia. Here the victim seems to lose the ability to form an integrated, interrelated representation of his or her world and his or her self together. The person speaks in ‘word salads’ that never get anywhere, indeed sometimes never become complete sentences. The person is unable to put together integrated plans of actions even at the level necessary to obtain sustenance, tend to bodily needs, or escape painful irritants. So on. Here, saying that unity of consciousness has shattered seems correct than split. The behaviour of these people seems to express no more than what we might call experience-fragments, each lasting a tiny length of time and unconnected to any others. In particular, except for the (usually semantically irrelevant) associations that lead these people from each entry to the next in the word salads they create, to be aware of one of these states is not to be aware of any others - or so to an evidentiary proposition.
In schizophrenia of this sort, the shattering of unified consciousness is part of a general breakdown or deformation of mental functioning: pertain to, desire, belief, even memory all suffer massive distortions. In another kind of case, the normal unity of consciousness seems to be just as absent but there does not seem to be general disturbance of the mind. This is what some researchers call dysexecutive syndrome. What characterizes the breakdown in the unity of consciousness here is that subjects are unable to consider two things together, even things that are directly related to one another. For example, such people cannot figure out whether a piece of a puzzle fits into a certain place even when the piece and the puzzle are both clearly visibly and the piece obviously fits. They cannot crack an egg into a pan. So on.
A disorder presenting similar symptoms is simultagnosia or Balint's syndrome (Balint was an earlier 20th century German neurologist). In this disorder, which is fortunately rare, patients see only one object located at one ‘place’ in the visual field at a time. Outside of a few ‘degrees of arc’ in the visual field, these patients say they see nothing and seem to be receiving no information (Hardcastle, in progress). In both dysexecutive disorder and simultagnosia (if we have two different phenomena here), subjects seem not to be aware of even two items in a single conscious state.
We can pin down what is missing in each case a bit more precisely. Recall the distinction between being conscious of individual objects and having unified consciousness of a number of objects at the same time introduced at the beginning of this article. Broadly speaking, we can think of the two phenomena isolated by this distinction as two stages. First, the mind ties together various sensory inputs into representations of objects. In contemporary cognitive research, this activity has come to be called binding (Hardcastle 1998 is a good review). Then, the mind ties these represented objects together to achieve unified consciousness of a number of them at the same time. (The first theorist to separate these two stages was Kant, in his doctrine of synthesis.) The first stage continues to be available to dysexecutive and simultagnosia patients: they continue to be aware of individual objects, events, etc. The damage seems to be to the second stage: it is the tying of objects together in consciousness that is impaired or missing altogether. The distinction can be made this way: these people can achieve some (z), unity of focus with respect to individual objects, but little or no unified consciousness of any of the three kinds over a number of objects.
The same distinction can also help make clear what is going on in the severe forms of schizophrenia just discussed. Like dysexecutive syndrome and simultagnosia patients, severe schizophrenics lack the ability to tie represented objects together, but they also seem to lack the ability to form unified representations of individual objects. In a different jargon, these people seem to lack even the capacity for object constancy. Thus their cognitive impairment is much more severe than that experienced by dysexecutive syndrome and simultagnosia patients.
With the exception of brain bisection patients, who do not evidence distortion of consciousness outside of specially contrived laboratory situations, the split or breach occurs naturally in all the patients just discussed. Indeed, they are a central class of the so-called ‘experiments of nature’ that are the subject-matter of contemporary neuropsychology. Since all the patients in whom these problems occur naturally are severely disadvantaged by their situation, this is further evidence that the ability to unify the contents of consciousness is central to proper cognitive functioning.
Is there anything common to the six situations of breakdowns in unified consciousness just sketched? How do they relate to (x), (Y) or (z)?
In brain bisection cases, the key evidence for a duality of some kind is that there are situations in which whatever is aware of some items being represented in the body in question is not aware of other items being represented in that same body at the same time. We looked at two examples of the phenomenon connection with the word TAXABLE and the doing of arithmetic. With respect to these represented items, there is a significant and systematically extendable situation in which to be aware of some of these items is not to be aware of others of them. This seems to be what motivates the judgment in us that these patients’ evidence a split in unified consciousness. If so, brain bisection cases are a straightforward case of a failure to meet the conditions for (x). However, they are more than that. Because the ‘centres of consciousness’ created in the lab do not communicate with one another except in the way that any mind can communicate with any other mind, there is also a breakdown in (Y). One subject of experience aware of itself as the single common subject of its experience seems to become two (in some measure at least).
In DID cases, and a central feature of the case is some pattern of amnesia. Again, this is a situation in which being conscious of some represented objects goes with not being conscious of others in a systematic way. The main difference is that the breach is at a time in brain bisection cases, across time in DID cases. So again the breakdown in unity consists in a failure to meet the conditions for (x). However, DID being diachronic, there is also a breakdown in (Y) across time - though there is continuity across time within each personality, there seems to be little or no continuity, conscious continuity at any rate, from one to another.
The same pattern is evident in the cases of severe schizophrenia, dysexecutive disorder and simultagnosia that we considered. In all three cases, consciousness of some items goes with lack of consciousness of others. In these cases, to be aware of a given item is precisely not to be aware of other relevant items. However, in the severe schizophrenia cases we considered, there is also a failure to meet the conditions of (z).
Hemi-neglect is a bit different. Here we do not have two or more ‘packages’ of consciousness and we do not have individual conscious states that are not unified with other conscious states. (Not so far as we know - for there to be conscious states not unified with the states on which the patient can report, there would have to be consciousness of what is going on in the side neglected by the subject with whom we can communicate and there is no evidence for this.) Here none of the conditions for (x), (y) or (z) fail to be met - but that may be because hemi-neglect is not a split or a breakdown in unified consciousness in the first place. It may be simply a shrinking of the range of phenomena over which otherwise intact unified consciousness amplifies..
It is interesting that none of the breakdown cases we have considered evidence damage to or destruction of the unity in (y). We have seen cases in which unified consciousness it might split at a time (brain bisection cases) or over time (DID cases) but not cases in which the unity itself is significantly damaged or destroyed. Nor is our sample unrepresentative; the cases we have considered are the most widely discussed cases in the literature. There do not seem to be many cases in which saying that is plausible (y), awareness of one-self as a single common subject, has been damaged or destroyed.
After a long hiatus, serious work on the unity of consciousness began in recent philosophy with two books on Kant, P. F. Strawson (1966) and Jonathan Bennett (1966). Both of them had an influence far beyond the bounds of Kant scholarship. Central to these works is an exploration of the relationship between unified consciousness, especially unified consciousness of self, and our ability to form an integrated, coherent representation of the world, a linkage that the authors took to be central to Kant's transcendental deduction of the categories. Whatever the merits of the claim for a sceptical judgment, their work set off a long line of writings on the supposed link. Quite recently the approach prompted a debate about unity and objectivity among Michael Lockwood, Susan Hurley and Anthony Marcel in Peacocke (1994).
Another issue that led philosophers back to the unity of consciousness, perhaps the next historically, was the neuropsychological results of brain bisection operations that we explored earlier. Starting with Thomas Nagel (1971) and continuing in the work of Charles Marks (1981), Derek Parfit (1971 and 1984), Lockwood (1989), Hurley (1998) and many others, these operations have been a major theme in work on the unity of consciousness since the 1970s. Much ink has been spilled on the question of what exactly is going on in the phenomenology of brain bisection patients. Nagel goes so far as to claim that there is no whole number of ‘centres of consciousness’ in these patients: there is too much unity to say "two,” yet too much splitting to say "one.”
Some recent work by Jocelyne Sergent (1990) might seem to support this conclusion. She found, for example, that when a sign ‘6’ was sent to one hemisphere of the brain in these subjects and a sign ‘7’ was sent to the other in such a way that crossover of information from one hemisphere to the other was extremely unlikely, they could say that the six is a smaller number than the seven but could not say whether the signs were the same or different. It is not certain that Sergent's work does support Nagel's conclusions. First, Sergent's claims are controversial - not, but all researchers have been able to replicate them. Second, even if the data are good, the interpretation of them is far from straightforward. In particular, they seem to be consistent with there being a clear answer to any precise ‘one or two?’ question that we could ask. (’Unified consciousness of the two signs with respect to numerical size?’ Yes. ‘Unified consciousness of the visible structure of the signs?’ No). If so, the fact that there is obviously mixed evidence, some pointing to the conclusion ‘one’, some pointing to the conclusion ‘two’, supports the view expressed by Nagel that there may be no whole number of subjects that these patients are.
Much of the work since Nagel has focussed on the same issue of the kind of split that the laboratory manipulation of brain bisection patients induces. Some attention has also been paid to the implications of these splits. For example, could one hemisphere commit a crime in such a way that the other could not justifiably be held responsible for it? Or, if such splitting occurred regularly and was regularly followed by merging with ‘halves’ from other splits, what would the implications are for our traditional notion of what philosophers call ‘personal identity’, namely, being or remaining one and the same thing. (Here we are talking about identity in the philosopher's sense of being or remaining one thing, not in the sense of the term that psychologists use when they talk of such things as ‘identity crises’.)
Parfit has made perhaps the largest contributions to the issue of the implications of brain bisection cases for personal identity. Phenomena relevant to identity in things others than persons can be a matter of degree. This is well illustrated by the famous ship of Theseus example. Suppose that over the years, a certain ship in Theseus was rebuilt, boards by board, until every single board in it has been replaced. Is the ship at the end of the process the ship that started the process or not? Now suppose that we take all those rotten, replaced boards and reassemble them into a ship? Is this ship the original ship of Theseus or not? Many philosophers have been certain that such questions cannot arise for persons; identity in persons is completely clear and unambiguous, not something that could be a matter of degree as related phenomena obviously can be with other objects is a well-known example. As Parfit argues, the possibility of persons (or at any rate minds) splitting and fusing puts real pressure on such intuitions about our specialness; perhaps the continuity of persons can be as partial and tangled as the continuity of other middle-sized objects.
Lockwood's exploration of brain bisections cases go off in a different direction, two different directions in fact (we will examine the second below). Like Nagel, Marks, and Parfit, Lockwood has written on the extent to which what he calls ‘co-consciousness’ can split. (’Co-consciousness’ is the term that many philosophers now use for the unity of consciousness; roughly, two conscious states are said to be co-conscious when they are related to one another as conscious states are related to one another in unified consciousness.) He also explores the possibility of psychological states that are not determinately in any of the available ‘centres of consciousness’ and the implications of this possibility for the idea of the specious present, the idea that we are directly and immediately aware of a certain tiny spread of time, not just the current infinitesimal moment of time. He concludes that the determinateness of psychological states being in an available ‘centre of consciousness’ and the notion that psychological states spread over at least a small amount of time in the specious might present stand or fall together.
Some philosophers interested in pathologies of unified consciousness examine more than brain bisection cases. In what is perhaps the most complex work on the unity of consciousness to date, Hurley examines most of the kinds of breakdown phenomena that we introduced earlier. She starts with an intuitive notion of co-consciousness that she does not formally define. She then explores the implications of a wide range of ‘experiments of nature’ and laboratory experiments for the presence or absence of co-consciousness across the psychological states of a person. For example, she considers acallosal patients (people born without a corpus callosum). When present, the corpus callosum is the chief channel of communication between the hemispheres. When it is cut, generating what looks like is possible two centres of consciousness, two internally co-conscious systems that are not co-consciousness with one another. Hurley argues that in patients in whom it never existed, things are not so clear. Even though the channels of communication in these patients are often in part external (behavioural cuing activity, etc.), the result may still be a single co-conscious system. That is to say, the neurological and behavioural basis of unified consciousness may be very different in different people.
Hurley also considers research by Trewarthen in which a patient is conscious of some object seen by, say, the right hemisphere until her left hand, which is controlled by the right hemisphere, reaches for it. Somehow the act of reaching for it seems to obliterate the consciousness of it. Very strange - how can something pop into and disappear from unified consciousness in this way? This leads her to consider the notion of partial unity. Could two centres of consciousness, A and B, though not co-conscious with one another, nonetheless both be co-conscious with some third thing, e.g., the volitional system B (the system of intentions, desires, etc.?). If so, ‘co-conscious’ is not a transitive relationship - A could be co-conscious with B and C could be co-conscious with B without A being co-conscious with C. This is puzzling enough. Even more puzzling would be the question of how activation of the system B with which both A and C are co-conscious could result in either A or C ceasing to be conscious of an object aimed at by B.
Hurley's response to Trewarthen's cases (and Sergent's cases that we examined in the previous section) is to accept that intention can obliterate consciousness and then distinguish times. At any given time in Trewarthen's cases, the situation with respect to unity is clear. That the picture does not conform to our usual expectations for diachronic singularity or transitivity then becomes simply an artefact of the cases, not a problem. It is not made clear how this reconciles Sergent's evidence with unity. One strategy would be the one we considered earlier: make the questions more precise. For precise questions, there seems to be a coherent answer about unity for every phenomenon Sergent describes.
Hurley also considers what she calls Marcel's case. Here subjects are asked to report the appearance of some item in consciousness in three ways at the same time - say, by blinking, pushing a button, and saying, ‘I see it’. Remarkably, any of these acts can be done without the other two. The question is, What does this imply for unified consciousness? In a case in which the subject pushes the button but neither blinks nor says anything, for example, is the hand-controller aware of the object while the blink-controller and the speech-controller are not? How could the conscious system become fragmented in such a way?
Hurley's suggestion is: they can't. What induces the appearance of incoherence about unity is the short time scale. Suppose that it takes some time to achieve unified consciousness, perhaps because some complex feedback processes are involved. If that were the case, then we do not have a stable unity situation in Marcel's case. The subjects are not given enough time to achieve unified consciousness of any kind.
There is a great deal more to Hurley's work. She urges, for example, that there a normative dimension to unified consciousness -- conscious states have to cohere for unified consciousness to result. Systems in the brain have to achieve her calls ‘dynamic singularity’ - being a single system - for unified consciousness to result.
A third issue that got philosophers working on the unity of consciousness again is binding. Here the connection is more distant because binding as usually understood is not unified consciousness as we have been discussing it. Recall the two stages of cognition laid out earlier. First, the mind ties together various sensory inputs into representations of objects. Then the mind ties these represented objects to one other to achieve unified consciousness of a number of them at the same time. It is the first stage that is usually called binding. The representations that result at this stage need not be conscious in any of the ways delineating earlier -- many perfectly good representations affect behaviour and even enter memory without ever becoming conscious. Representations resulting from the second stage need not be conscious, either, but when they are, we have at least some of the kinds of unified consciousness delineated.
In the past few decades, philosophers have also worked on how unified consciousness relates to the brain. Lockwood, for example, thinks that relating consciousness to matter will involve more issues on the side of matter than most philosophers think. (We mentioned that his work goes off in two new directions. This is the second one.) Quantum mechanics teach us that the way in which observation links to physical reality is a subtle and complex matter. Lockwood urges that our conceptions will have to be adjusted on the side of matter as much as on the side of mind if we are to understand consciousness as a physical phenomenon and physical phenomena as open to conscious observation. If it is the case not only that our understanding of consciousness is affected by how we think it might be implemented in matter but also that process of matter are or can be affected by our (conscious) observation of them, then our picture of consciousness stands as ready to affect our picture of matter as vice-versa.
The Churchlands, Paul M. and Patricia S. and Daniel Dennett (1991) has radical views of the underlying architecture of unified consciousness. The Churchlands see unity itself much as other philosophers do. They do argue that the term ‘consciousness’ covers a range of different phenomena that need to be distinguished from one another but the important point here is that they urge that the architecture of the underlying processes probably consist not of transformations of symbolically encoded objects of representations, as most philosophers have believed, but of vector transformations in what are called phase spaces. Dennett articulates an even more radical view, encompassing both unity and underlying architecture. For him, unified consciousness is simply a temporary ‘virtual captain’, a small group of related information-parcels that happens to gain temporary dominance in a struggle for control of such cognitive activities as self-monitoring and self-reporting in the vast array of microcircuits of the brain. We take these transient phenomena to be more than they are because each of them is the ‘me’ of the moment; the temporary coalition of conscious states winning at the moment is what I am, is the self. Radical implementation, narrowed range and transitoriness notwithstanding, when unified consciousness is achieved, these philosophers tend to see it in the way we have presented it.
Dennett's and the Churchlands' views fit naturally with a dynamic systems view of the underlying neural implementation. The dynamic systems view is the view that unified consciousness is a result of certain self-organizing activities in the brain. Dennett thinks that given the nature of the brain, a vast assembly of neurons receiving electrochemical signals from other neurons and passing such signals to yet other neurons, cognition could not take any form other than something like a pandemonium of competing bits of content, the ones that win the competitions being the ones that are conscious. The Churchlands don't tend to agree with Dennett about this. They see consciousness as a state of the brain, the ‘wet-ware’, not a result of information processing, of ‘software’. They also advocate a different picture of the underlying neurological process. As we said, they think that transformations of complex vectors in a multi dimensional phase space are the crucial processes, not competition among bits of content. However, they agree that it is very unlikely that the processes that subserve unified consciousness are sentence-like or language-like at all. It is too early to say whether these radically novel pictures of what the system that implements unified consciousness is like will hold any important implications for what unified consciousness is or when it is present.
Hurley is also interested in the relationship of unified consciousness to brain physiology. Saying it of her that she resists certain standard ways of linking them would be truer, however, than to say that she herself links them. In particular, while she clearly thinks that physiological phenomena have all sorts of implications and give rise to all sorts of questions about the unity of consciousness, she strongly resists any simplistic patterns of connection. Many researchers have been attracted by some variant of what she calls the isomorphism hypothesis. This is the idea that changes in consciousness will parallel changes in brain structure or function. She wants to insist, to the contrary, that often two instances of the same change in consciousness will go with very different changes in the brain. We saw an example in the last section. In most of us, unified consciousness is closely linked to an intact, functioning corpus callosum. However, in acallosal people, there may be the same unity but achieved by mechanisms such as cuing activity external to the body that are utterly different from communication though a corpus callosum. Going the opposite way, different changes in consciousness can go with the same changes to structure and function in the brain.
Two philosophers have gone off in directions different from any of the above, Stephen White (1991) and Christopher Hill (1991). White's main interest is not the unity of consciousness as such but what one might call the unified locus of responsibility - what it is that ties something together to make it a single agent of actions, i.e., something to which attributions of responsibility can appropriately be made. He argues that unity of consciousness is one of the things that go into becoming unified as such an agent but not the only thing. Focussed coherent plans, a continuing single conception of the good, with reason of a good autobiographical memory, certain future states of persons mattering to us in a special way (mattering to us because we take them to be future states of ourselves, one would say if it were not blatantly circular), a certain continuing kind and degree of rationality, certain social norms and practices, and so forth. In his picture of moral responsibility, unbroken unity of consciousness at and over time is only a small part of the story.
Hill's fundamental claim is that a number of different relationships between psychological states have a claim to be considered unity relationships, including: being owned by the same subject, being [phenomenally] next to (and other relationships that state in the field of consciousness appear to have to one another), both being the object of a single other conscious state, and jointly having the appropriate sorts of effects (functions). An interesting question, one that Hill does not consider, is whether all these relations are what interests us when we talk about the unity of consciousness or only some of them (and if only some of them, which ones). Hill also examines scepticism about the idea that clearly bounded individual conscious states exist. Since we have been assuming throughout that such states do exist, it is perhaps fortunate that Hill argues that we could safely do so.
In some circles, the idea that consciousness has a special kind of unity has fallen into disfavour. Nagel (1971), Donald Davidson (1982), and Dennett (1991) have all urged that the mind's unity has been greatly overstated in the history of philosophy. The mind, they say, works mostly out of the sight and the control of consciousness. Moreover, even states and acts of ours that are conscious can fail to cohere. We act against what we know perfectly well to be our own most desired course of action, for example, or do things while telling ourselves that we must avoid doing them. There is an approach to the small incoherencies of everyday life that does not requires us to question whether consciousness is unified in this way, the Freudian approach (e.g., Freud 1916/17). This approach accepts that the unity of consciousness exists much as it presents itself but argues that the range of material over which it extends is much smaller than philosophers once thought. This latter approach has some appeal. If something is out of sight and/or control, it is out of the sight or control of what? The answer would seem to be, the unified conscious mind. If so, the only necessary difference among the pre-twentieth centuries visions of unified consciousness as ranging over everything in the mind and our current vision of unified consciousness is that the range of psychological phenomena over which unified consciousness ranges has shrunk.
A final historical note. At the beginning of the 21st century, work on the unity of consciousness continues apace. For example, a major conference was recently devoted to the unity of consciousness, the Association for the Scientific Study of Consciousness Conference held in Brussels in 2000 (ASSC5) Encyclopaedias of philosophy (such as this one) and of cognitive science are commissioning articles on the topic. Psychologists are taking up the issue. Bernard Baars (1988, 1997) notion of the global workspace is an example. Another example is work on the role of unified consciousness in precise control of attention. However, the topic is not yet at the centre of consciousness studies. One illustration of this is that it can still be missing entirely in anthologies of current work on consciousness.
With a different issue, philosophers used to think that the unity of consciousness has huge implications for the nature of the mind, indeed entails that the mind could not be made out of matter. We also saw that the prospects for this inference are not good. What about the nature of consciousness? Does the unity of consciousness have any implications for this issue?
There are currently at least three major camps on the nature of consciousness. One camp sees the ‘felt quality’ of representations as something unique, in particular as quite different from the power of representations to change other representations and shape belief and action. On this picture, representations could function much as they do without it being like anything to have them. They would merely not be conscious. If so, consciousness may not play any important cognitive role at all, its unity included (Jackson 1986; Chalmers 1996). A second camp holds, to the contrary, that consciousness is simply a special kind of representation (Rosenthal 1991; Dretske 1995; Tye 1995). A third holds that what we label ‘consciousness’ are really something else. On this view, consciousness will in the end be ‘analysed away’ - the term is too coarse-grained and presents things in too unquantifiable a way to have any use in a mature science of the mind.
The unity of consciousness obviously has strong implications for the truth or falsity of any of these views. If it is as central and undeniable as many have suggested (we saw some of the arguments earlier), its existence may cut against the third, eliminativist position a bit. With respect to the other two positions, the unity of consciousness seems neutral.
Whatever its implications for other issues, the unity of consciousness seems to be a real feature of the human mind, indeed central to it. If so, any complete picture of the mind will have to provide an account of it. Even those who hold that the extent to which consciousness is unified has been overrated owe us an account of what has been overrated.
To say one has an experience that is conscious (in the phenomenal sense) is to say that one is in a state of its seeming to one some way. In another formulation, to say experience is conscious is to say that there is something it's like for one to have it. Feeling pain and sensing colours are common illustrations of phenomenally conscious states. Consciousness has also been taken to consist in the monitoring of one's own states of mind (e.g., by forming thoughts about them, or by somehow "sensing" them), or else in the accessibility of information to one's capacities for rational control or self-report. Intentionality has to do with the directedness or aboutness of mental states -- the fact that, for example, one's thinking is of or about something. Intentionality includes, and is sometimes taken to be equivalent to, what is called ‘mental representation.
It can seem that consciousness and intentionality pervade mental life -perhaps, but one or both somehow constitute what it is to have a mind. But achieving an articulate general understanding of either consciousness or intentionality presents, an enormous challenge, part of which lies in figuring out how the two are related. Is one in some sense derived from or dependent on the other? Or are they perhaps quite independent and separate aspects of mind?
One understanding frequent among philosophers, consciousness is a certain feature shared by sense-experience and imagery, perhaps belonging also to a broad range of other mental phenomena (e.g., episodic thought, memory, and emotion). It is the feature that consists in its seeming some way to one to have experiences. To put it another way: conscious states are states of its seeming somehow to a subject.
For example, it seems to you some way to see red, and seems to you (some other way) to hear a crash, to visualize a triangle, and to suffer pain. The sense of ‘seems’ relevant here may be brought out by noting that, in the last example, we might just as well speak of the way it feels to be in pain. And - some will want to say - in the same sense, it seems to you some way to think through the answer to a math problem, or to recall where you parked the car, or to feel anger, shame, or elation. (Note however, that it is not simply to be assumed that saying it seems some way to you to have an experience is equivalent to saying that the experience itself seems or appears some way to you - that it is an - object of appearance. The point is just that the way something sounds to you, the way something looks to you, etc., all constitute ‘ways of seeming.’) States that are conscious in this sense are said to have some phenomenal character or other - their phenomenal character being the specific way it seems to one to have a given experience. Sometimes this is called the ‘qualitative’ or ‘subjective’ character of experience.
Another oft-used means for trying to get at the relevant notion of consciousness, preferable to some, is to say that there is, in a certain sense, always ‘something it is like’ to be in a given conscious state - something it's like for one who is in that state. Relating the two locutions, we might say: there is something it is like for you to see red, to feel pain, etc., and the way it seems to you to have one of these experiences is what it is like for you to have it. The phenomenal character of an experience then, is what someone would inquire about by asking, e.g., ‘What is it like to experience orgasm?’ - and it is what we speak of when we say that we know what that is like, even if we cannot convey this to one who doesn't know. And, if we want to speak of persons, or other creatures (as distinct from their states) being conscious, we will say that they are conscious just if there is something it is like for them to be the creatures they are -- for example, something it is like to be a bat.
The examples of conscious states given comprise a various lot. But some sense of their putative unity as instances of consciousness might be gained by contrasting them with what we are inclined to exclude, or can at least conceive of excluding, from their company. Much of what goes on, but we would ordinarily believe is not (or at any rate, we may well suppose is not) conscious in the sense at issue. The leaf's fall from a tree branch, we may suppose, is not a conscious state of the leaf - a state of its seeming somehow to the leaf. Nor, for that matter, is a person's fall off a branch a conscious state of that person - rather, it is the feeling of falling that is conscious, if anything is. Dreaming of falling would also be a conscious experience in this sense. But, while we can in some way be said to sense the position of our limbs even while dreamlessly asleep, we may still suppose that this proprioception (though perhaps in some sense a mental or cognitive affair) is not conscious - we may suppose that it does not then seem (or feel) any way to us sleepers to sense our limbs, as ordinarily it does when we are awake.
The way of seeming’ or ‘what it's like’ conception of consciousness I have just invoked is sometimes marked by the term ‘phenomenal consciousness.’ But this qualifier ‘phenomenal’ suggests that there are other kinds of consciousness (or perhaps, other senses of ‘consciousness’). Indeed there are, at least, other ways of introducing notions of consciousness. And these may appear to pick out features or senses altogether distinct from that just presented. For example, it is said that some (but not all) that goes on in the mind is ‘accessible to consciousness.’ Of course this by itself does not so much specifies a sense of ‘conscious’ as put one in use. (One will want to ask: And just what is this ‘consciousness’ that has ‘access’ to some mental goings-on but not others, and what could ‘access’ mean here, anyway?) However, some have evidently thought that, rather than speak of consciousness as what has access, we should understand consciousness as itself a certain kind of susceptibility to access. For example, Daniel Dennett (1969) once theorized that one's conscious states are just those whose contents are available to one's direct verbal report - or, at least, to the ‘speech centre’ responsible for generating such reports. And Ned Block (1995) has proposed that, on one understanding of ‘conscious,’ (to be found at work in many ‘cognitive’ theories of consciousness) a conscious state is just a ‘representation poised for free use in reasoning and other direct ‘rational’ control of action and speech.’ Block labels consciousness in this sense ‘excess consciousness.’
Block would insist that we should distinguish phenomenal consciousness from ‘access consciousness,’ and he argues that a mental representation's being poised for use in reasoning and rational control of action is neither a necessary nor a sufficient condition for the state's being phenomenally conscious. Similarly he distinguishes phenomenal consciousness from what he calls ‘reflexive consciousness’ - where this has to do with one's capacity to represent one's mind's to one-self - to have, for example, thoughts about one's own thoughts, feelings, or desires. Such a conception of consciousness finds some support in a tendency to say that conscious states of mind are those one is ‘conscious of’ or ‘aware of’ being in, and to interpret this ‘of’ to indicate some kind of reflexivity is involved - wherein one represents one's own mental representations. On one prominent variant of this conception, consciousness is taken to be a kind of scanning or perceiving of one's own psychological states or processes - an ‘inner sense.’
Block's threefold division of phenomenal, access, and reflexive consciousness need not be taken to reflect clear and coherent distinctions already contained in our pre-theoretical use of the term ‘conscious.’ Block himself seems to think that (on the contrary) our initial, ordinary use of ‘conscious’ is too confused even to count as ambiguous. Thus in articulating an interpretation, or set of interpretations, of the term adequate to frame theoretical issues, we cannot simply describe how it is currently employed - we must assign it a more definite and coherent meaning than extant in common usage.
Whether or not this is correct, getting a solid ground here is not easy, and a number of theorists of consciousness would balk at proceeding on the basis of Block's proposed threefold distinction. Sometimes the difficulty may be merely terminological. John Searle, for example, would recognize phenomenal consciousness, but deny Block's other two candidates are proper senses of ‘conscious’ at all. The reality of some sort of access and reflexivity is apparently not at issue - just whether either captures a sense of ‘conscious’ (perhaps confusedly) woven into our use of the term. However, in contrast to both Block and Searle, there are also those who raise doubt that there is a properly phenomenal sense we can apply, distinct from both of the other two, for us to pick out with any term. This is not just a dispute about words, but about what there is for us to talk about with them.
The substantive issues here are very much bound up with differences over the proper way to conceive of the relationship between consciousness and intentionality. If there are distinct senses in which states of mind could be correctly said to be ‘conscious’ (answering perhaps to something like Block's three-fold distinction), then there will be distinct questions we can pose about the relation between consciousness and intentionality. But if one of Block's alleged senses is somehow fatally confused, or if he is wrong to distinguish it from the others, or if it is the sense of no term we can with warrant apply to ourselves or our states, then there will be no separate question in which it figures we should try to answer. Thus, trying to work out a reasoned view about what we are (or should be) talking about when we talk about consciousness is an unavoidable and non-trivial part of trying to understand the relation between consciousness and intentionality.
To clarify further the disputes about consciousness and their links to questions about its relation to intentionality, we need to get an initial grasp of the relevant way the terms ‘intentionality’ and ‘intentional’ are used in philosophy of mind.
Previously, some indication of why it is difficult to get a theory of consciousness started. While the term ‘conscious’ is not esoteric, its use is not easily characterized or rendered consistent in a manner providing some uncontentious framework for theoretical discussion. Where the term ‘intentional’ is concerned, we also face initially confusing and contentious usage. But here the difficulty lies partly in the fact that the relevant use of cognate terms is simply not that found in common speech (as when we speak of doing something ‘intentionally’). Though ‘intentionality,’ in the sense here at issue, does seem to attach to some real and fundamental (maybe even defining) aspect of mental phenomena, the relevant use of the term is tangled up with some rather involved philosophical history.
One way of explaining what is meant by ‘intentionality’ in the (more obscure) philosophical sense is this: it is that aspect of mental states or events that consists in their being of or about things, as pertains to the questions, ‘What are you thinking of?’ And, what are you thinking about?’ Intentionality is the aboutness or directedness of mind (or states of mind) to things, objects, states of affairs, events. So if you are thinking about San Francisco, or about the increased cost of living there, or about your meeting someone there at Union Square - your mind, your thinking, is directed toward San Francisco, or the increased cost of living, or the meeting in Union Square. To think at all is to think of or about something in this sense. This ‘directedness’ conception of intentionality plays a prominent role in the influential philosophical writings of Franz Brentano and those whose views developed in response to his.
But what kind of ‘aboutness’ or ‘of-ness’ or ‘directedness’ is this, and to what sorts of things does it apply? How do the relevant ‘intentionality-marking’ senses of these words (‘about,’ ‘of,’ ‘directed’) differ from? : the sense in which the cat is wandering ‘about’ the room; the sense in which someone is a person ‘of’ high integrity; the sense in which the river's course is ‘directed’ toward the fields?
It has been said that the peculiarity of this kind of directedness/aboutness/of-ness lies in its capacity to relate thought or experience to objects that (unlike San Francisco) do not exist. One can think about a meeting that has not, or never will occur; one can think of Shangri La, or El Dorado, or the New Jerusalem; one may think of their shining streets, of their total lack of poverty, or of their citizens' peculiar garb. Thoughts, unlike roads, can lead to a city that is not there.
But to talk in this way only invites new perplexities. Is this to say (with apparent incoherence) that there are cities that do not exist? And what does it mean to say that, when a state of mind is in fact ‘directed toward’ something that does exist, that state nevertheless could be directed toward something that does not exist? It can well seem to be something very fundamental to the nature of mind that our thoughts, or states of mind more generally, can be of or about things or ‘point beyond themselves.’ But a coherent and satisfactory theoretical grasp of this phenomenon of ‘mental pointing’ in all its generality is difficult to achieve.
Another way of trying to get a grip on the topic asks us to note that the potential for a mental directedness toward the non-existent is evidently closely associated with the mind's potential for falsehood, error, inaccuracy, illusion, hallucination, and dissatisfaction. What makes it possible to believe (or even just suppose) something about Shangri La is that one can falsely believe (or suppose) that something exists? In the case of perception, what makes it possible to seem to see or hear what is not there is that one's experience may in various ways be inaccurate, nonveridical, subject to illusion, or hallucinatory. And, what makes it possible for one's desires and intentions to be directed toward what does not and never will exist is that one's desires and intentions can be unfulfilled or unsatisfied. This suggests another strategy for getting a theoretical hold on intentionality, employing a notion of satisfaction, stretched to encompass susceptibility to each of these modes of assessment, each of these ways in which something can either go right, or go wrong (true/false, veridical/nonveridical, fulfilled/unfulfilled), and speak of intentionality in terms of having ‘conditions of satisfaction.’ On John Searle's (1983) conception, intentional states are those having conditions of satisfaction. What are conditions of satisfaction? In the case of belief, these are the conditions under which the belief is true; in the case of perception, they are the conditions under which sense-experience is veridical; in the case of intention, the conditions under which an intention is fulfilled or carried out.
However, while the conditions of satisfaction approach to the notion of intentionality may furnish an alternative to introducing this notion by talking of ‘directedness to objects,’ it is not clear that it can get us around the problems posed by the ‘directedness’ talk. For instance, what are we to say where thoughts are expressed using names of nonexistent deities or fictional characters? Will we do away with a troublesome directedness to the nonexistent by saying that the thoughts that Zeus is Poseidon's brother, and that Hamlet is a prince, is just false? This is problematic. Moreover, how will we state the conditions of satisfaction of such thoughts? Will this not also involve an apparent reference to the nonexistent?
A third important way of conceiving of intentionality, one particularly central to the analytic tradition derived from the study of Frege and Russell whom asks us to concentrate on the notion of mental (or intentional) content. Often, it is assumed: to have intentionality is to have content. And frequently mental content is otherwise described as representational or informational content - and ‘intentionality’ (at least, as this applies to the mind) is seen as just another word for what is called ‘mental representation,’ or a certain way of bearing or carrying information.
But what is meant by ‘content’ here? As a start we may note: the content of thought, in this sense, is what, is reported when answering the question, ‘What does she think?’ by something of the form, ‘She thinks that p.’ And the content of thought is what two people are said to share, when they are said to think the same thought. (Similarly, the content of belief is what two people share when they hold the same belief.) Content is also what may be shared in this way even while ‘psychological modes’ of states of mind may differ. For example: believing that I'll soon be bald and fearing that I'll soon be bald share the content: that I'll soon be bald.
Also, commonly, content is taken as not only that which is shared in the ways illustrated, but that which differs in a way revealed by considering certain logical features of sentences we use to talk about states of mind. Notably: the constituents of the sentence that fills in for ‘p’ when we say ‘x thinks that p’ or ‘x believes that p’ are often interpreted in such a way that they display ‘failures of substitutivity’ of (ordinarily) co-referential or co-extensional expressions, and this appears to reflect differences in mental content. For example: if George W. Bush is the eldest son of the vice-president under Ronald Reagan, and George W. Bush is the current U.S. President, then it can be validly inferred that the eldest son of Reagan's vice-president is the current U.S. President. However, we cannot always make the same sort of substitutions of terms when we use them to report what someone believes. From the fact that you believe that George W. Bush is the current U.S. President, we cannot validly infer that you believe that the eldest son of Reagan's vice-president is the current U.S. President. That last may still be false, even if George W. Bush is indeed the eldest son. These logical features of the sentences ‘x believes that George W. Bush is the current U.S. President’ and ‘x believes that George W. Bush is the eldest son of Reagan's vice-president’ seem to reflect the fact that the beliefs reported by their use have different contents: these sentences are used by someone to state what is believed (the belief content), and what is believed in each case is not just the same. Someone's belief may have the one content without having the other.
Similar observations can be made for other intentional states and the reports made of them - especially when these reports contain an object clause beginning with ‘that’ and followed by a complete sentence (e.g., she thinks that p; he intends that p; she hopes that p; he fears that p; she sees that p). Sometimes it is said that the content of the states is ‘given’ by such a ‘that p’ clause when ‘p’ is replaced by a sentence - the so-called ‘content clause.’
This ‘possession of content’ conception of intentionality may be coordinated with the ‘conditions of satisfaction’ conception roughly as follows. If states of mind contrast in respect of their satisfaction (say, one is true and the other false), they differ in content. (One and the same belief content cannot be both true and false - at least not in the same context at the same time.) And if one says what the intentional content of a state of mind is, one says much or perhaps all of what conditions must be met if it is to be satisfied - what its conditions of truth, or veridicality, or fulfilment, are. But one should be alert to how the notion of content employed in a given philosopher's views is heavily shaped by these views, and one should note how commonly it is held that the notion of content is in this or that way ambiguous or in need of refinement. (Consider, for example: Jerry Fodor's) defence of a distinction between ‘narrow’ and ‘wide’ content; Edward Zalta's (1988) distinction between ‘cognitive’ and ‘objective’ content; and John Perry's (2001) distinction between ‘reflexive' and ‘subject-matter’ content. It is arguable that each of these gates of entry into the topic of intentionality (directedness; conditions of satisfaction; mental content) opens onto a unitary phenomenon. But evidently there is also considerable fragmentation in the conceptions of both consciousness and intentionality that are in the field. To get a better grasp of some of the ways the relationship between consciousness and intentionality can be viewed, without begging questions or trying to present a positive theory on the topic, it is useful to take a look at the recent history of thinking about intentionality, in a way that will bring several issues about its relationship with consciousness to the fore. Together with the preceding discussion, this should provide the background necessary for examining some of the differences that divide those who theorize about consciousness that are very intimately involved with views of the consciousness-intentionality relation.
If we are to acknowledge the extent to which the notion of intentionality is the creature of philosophical history, we have to come to terms with the divide in twentieth century western philosophy between so-called ‘analytic’ and ‘continental’ philosophical traditions. Both have been significantly concerned with intentionality. But differences in approach, vocabulary, and background assumptions have made dialogue between them difficult. It is almost inevitable, in a brief exposition, to give largely independent summaries of the two. We will start with the ‘continental’ side of the story - more, specifically, with the phenomenological movement in continental philosophy. However, while these traditions have developed without a great deal of intercommunication, they do have common sources, and have come to focus on issues concerning the relationship of consciousness and intentionality that are recognizably similar.
A thorough look at the historical roots of controversies over consciousness and intentionality would take us farther into the past than it is feasible to go in this article. A relatively recent, convenient starting point would be in the philosophy of Franz Brentano. He more than any other single thinker is responsible for keeping the term ‘intentional’ alive in philosophical discussions of the last century or so, with something like its current use, and was much concerned to understand its relationship with consciousness. However, it is worth noting that Brentano himself was very aware of the deep historical background to his notion of intentionality: he looked back through scholastic discussions (crucial to the development of Descartes' immensely influential theory of ideas), and ultimately to Aristotle for his theme of intentionality. One may well go further back, to Plato's discussion (in the Sophist, and the Theaetetus) of difficulties in making sense of false belief, and yet further still, to the dawn of Western Philosophy, and Parmenides' attempt to draw momentous consequences from his alleged finding that it is not possible to think or speak of what is not.
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