Neuroscience of free will


Neuroscience of free will

Neuroscience of free will refers to recent neuroscientific investigations shedding light on the question of free will, which is a philosophical and scientific question as to whether, and in what sense, rational agents exercise control over their actions or decisions. As it has become possible to study the living brain, researchers have begun to watch decision-making processes at work.

The field itself remains highly controversial as there is no consensus among researchers about the significance of findings, their meaning, or what conclusions may be drawn. In the light of recent studies, there lies the real possibility that the experience of "will", and its role in human choice, requires re-conceptualization. While this would carry implications for moral responsibility in general, the research below is still new enough to warrant only tentative conclusions.

Overview

...the current work is in broad agreement with a general trend in neuroscience of volition: although we may experience that our conscious decisions and thoughts cause our actions, these experiences are in fact based on readouts of brain activity in a network of brain areas that control voluntary action...It is clearly wrong to think of [the judgement of will] as a prior intention, located at the very earliest moment of decision in an extended action chain. Rather, W seems to mark an intention-in-action, quite closely linked to action execution.

-Patrick Haggard[1] discussing an in-depth experiment by Itzhak Fried[2]

One significant finding of modern studies is that a person's brain seems to commit to certain decisions before the person becomes aware of having made them (see right). Researchers have found delays of about half a second. With contemporary brain scanning technology, scientists in 2008 were able to predict with 60% accuracy whether subjects would press a button with their left or right hand up to 10 seconds before the subject became aware of having made that choice.[3] These and other findings have led some scientists, like Patrick Haggard, to reject some forms of "free will". To be clear, no single study would disprove all forms of free will. This is because the term "free will" can encapsulate different hypotheses, each of which must be considered in light of existing empirical evidence. It is quite likely that a large range of cognitive operations are necessary to freely press a button. Research at least suggests that our conscious self does not initiate all behaviours. Instead, the conscious self is somehow alerted to behaviours that the rest of the brain and body are already planning and performing. These findings do not forbid conscious experience from playing some moderating role (although this page does discuss studies suggesting that moderating and cancelling an action is an unconscious process too). The key is that the unconscious processes play a much larger role in behaviour, because they are what first initiate actions, whereas self awareness may only recognize that an action has been prepared.

It may be possible, then, that our intuitions about the role of our conscious "intentions" have led us astray; it may be the case that we have confused correlation with causation by believing that conscious awareness necessarily causes the body's movement. This possibility is bolstered by findings in neurostimulation, brain damage, but also research into introspection illusions. Such illusions show that humans do not have full access to various internal processes. The discovery that humans possess a determined will would have implications for moral responsibility. Neuroscientist and author Sam Harris believes this is the case, but says we should never have expected we had libertarian free will. He argues that "Thoughts simply arise in the brain. What else could they do? The truth about us is even stranger than we may suppose: The illusion of free will is itself an illusion".[4]

There have been a number of problems regarding studies of free will.[5] Particularly in earlier studies, research relies too much on the introspection of the participants (other research shows that things such as introspective estimates of event timing are not accurate). The conscious decision may be made elsewhere in the brain before conscious realization, leaving room for free will even if the conscious realization comes delayed.[5][clarification needed] Many brain activity measures have been insufficient and primitive as there is no good independent brain-function measure of the conscious generation of intentions, choices, or decisions. The conclusions drawn from measurements that have been made are debatable too, as they don't necessarily tell, for example, what a sudden dip in the readings are representing. In other words, the dip might have nothing to do with unconscious decision, since many other mental processes are going on while performing the task.[5] Some of the research mentioned here has gotten more advanced, however, even recording individual neurons in live volunteers.[2]

These studies have only just begun to shed light on the role that consciousness plays in actions and it is too early to draw very strong conclusions about many "free will"s. It is worth noting that such experiments - so far - have dealt only with free will decisions made in short time frames (seconds) and may not have direct bearing on free will decisions made ("thoughtfully") by the subject over the course of many seconds, minutes, hours or longer.

The Libet experiment

A pioneering experiment in this field was conducted by Benjamin Libet in the 1980s, in which he asked each subject to choose a random moment to flick their wrist while he measured the associated activity in their brain (in particular, the build-up of electrical signal called the readiness potential). Although it was well known that the readiness potential preceded the physical action, Libet asked how the readiness potential corresponded to the felt intention to move. To determine when the subject felt the intention to move, he asked her to watch the second hand of a clock and report its position when she felt that she had felt the conscious will to move.[6]

Libet's experiment: (0) repose, until (1) the readiness potential is detected, (2) the volunteer memorizes a dot position upon feeling their intention, and (3) then acts.

Libet found that the unconscious brain activity leading up to the conscious decision by the subject to flick his or her wrist began approximately half a second before the subject consciously felt that she had decided to move.[6][7] Libet's findings suggest that decisions made by a subject are first being made on a subconscious level and only afterward being translated into a "conscious decision", and that the subject's belief that it occurred at the behest of her will was only due to her retrospective perspective on the event.

The interpretation of these findings has been criticized by Daniel Dennett, who argues that people will have to shift their attention from their intention to the clock, and that this introduces temporal mismatches between the felt experience of will and the perceived position of the clock hand.[8][9] Consistent with this argument, subsequent studies have shown that the exact numerical value varies depending on attention.[10][11] Despite the differences in the exact numerical value, however, the main finding has held.[12][13][14] Philosopher Alfred Mele criticizes this design for other reasons. Having attempted the experiment himself, Mele explains that "the awareness of the intention to move" is an ambiguous feeling at best. For this reason he remained skeptical of interpreting the subjects' reported times for comparison with their 'readiness potential'.[15]

Investigating Libet's findings

Typical recording of the readiness potential. Benjamin Libet investigated whether this neural activity corresponded to the "felt intention" (or will) to move of experimental subjects.

In a variation of this task, Haggard and Eimer asked subjects to decide not only when to move their hands, but also to decide which hand to move. In this case, the felt intention correlated much more closely with the "lateralized readiness potential" (LRP), an ERP component which measures the difference between left and right hemisphere brain activity. Haggard and Eimer argue that the feeling of conscious will must therefore follow the decision of which hand to move, since the LRP reflects the decision to lift a particular hand.[10]

A more direct test of the relationship between the readiness potential and the "awareness of the intention to move" was conducted by Banks and Isham (2009). In their study, participants performed a variant of the Libet's paradigm in which a delayed tone followed the button press. Subsequently, research participants reported the time of their intention to act (e.g., Libet's "W"). If W were time-locked to the readiness potential, W would remain uninfluenced by any post-action information. However, findings from this study show that W in fact shift systematically with the time of the tone presentation, implicating that W is, at least in part, retrospectively reconstructed rather than pre-determined by the readiness potential.[16]

A study conducted by Jeff Miller and Judy Trevena (2009)[17] suggests that the readiness potential (RP) signal in Libet's experiments doesn't represent a decision to move, but that it's merely a sign that the brain is paying attention. In this experiment the classical Libet experiment was modified by playing an audio tone indicating to volunteers to decide whether to tap a key or not. The researchers found that there was the same RP signal in both cases, regardless of whether or not volunteers actually elected to tap, which suggests that the RP signal doesn't indicate that a decision has been made.[18] In a second experiment, researchers asked volunteers to decide on the spot whether to use left hand or right to tap the key while monitoring their brain signals, and they found no correlation among the signals and the chosen hand. This criticism has itself been criticized by free-will researcher Patrick Haggard, who mentions literature that distinguishes two different circuits in the brain that lead to action: a "stimulus-response" circuit and a "voluntary" circuit. According to Haggard, researchers applying external stimuli are testing neither the voluntary circuit, nor Libet's hypothesis about internally triggered actions.[19]

Discussed below (In the section "Timing intentions compared to actions") is one study that has replicated many of Libet's findings, whilst addressing some of the original criticisms[20]. It is also worth noting that, in 2011, Itzhak Fried replicated Libet's findings at the scale of the single neuron. This was accomplished with the help of volunteer epilepsy patients, who needed electrodes implanted deep in their brain for evaluation and treatment anyway. Now able to monitor awake and moving patients, the researchers replicated the timing anomalies that were discovered by Libet and are discussed in the following study.[2]

Unconscious actions

Timing intentions compared to actions

A recent study by Masao Matsuhashi and Mark Hallett [20] claims to have replicated Libet's findings without relying on subjective report or clock memorization on the part of participants. The authors believe that their method can identify the time (T) at which a subject becomes aware of her own movement. Matsuhashi and Hallet argue that this time not only varies, but often occurs after early phases of movement genesis have already begun (as measured by the readiness potential). They conclude that a person's awareness cannot be the cause of movement, and may instead only notice the movement.

The experiment

It was difficult to identify exactly when a person becomes aware of their action. Surprisingly, awareness seems to come only after actions have already begun in the brain

Matsuhashi and Hallett's study can be summarized thus. The researchers hypothesized that, if our conscious intentions are what causes movement genesis (i.e. the start of an action), then naturally, our conscious intentions should always occur before any movement has begun. Otherwise, if we ever become aware of a movement only after it has already been started, our awareness could not have been the cause of that particular movement. Simply put, conscious intention must precede action if it is its cause.

To test this hypothesis, Matsuhashi and Hallet had volunteers perform brisk finger movements at random intervals, while not counting or planning when to make such (future) movements, but rather immediately making a movement as soon as they thought about it. An externally controlled "stop-signal" sound was played at pseudo random intervals, and the volunteers had to cancel their intent to move if they heard a signal while being aware of their own immediate intention to move. Whenever there was an action (finger movement), the authors documented (and graphed) any tones that occurred before that action. The graph of tones before actions therefore only shows tones (a) before the subject is even aware of their "movement genesis" (or else they would have stopped or "vetoed" the movement), and (b) after it is too late to veto the action. This second set of graphed tones is of little importance here.

In this work, "movement genesis" is defined as the brain process of making movement, of which physiological observations have been made (via electrodes) indicating that it may occur before conscious awareness of intent to move (see Benjamin Libet).

By looking to see when tones started preventing actions, the researchers supposedly know the length of time (in seconds) that exists between when a subject holds a conscious intention to move and performs the action of movement. This moment of awareness (as seen in the graph below) is dubbed "T" (the mean time of conscious intention to move). It can be found by looking at the border between tones and no tones. This enables the researchers to estimate the timing of the conscious intention to move without relying on the subject's knowledge or demanding them to focus on a clock. The last step of the experiment is to compare time T for each subject with their Event-related potential (ERP) measures (e.g. seen in this page's lead image), which reveal when their finger movement genesis first begins.

The researchers found that the time of the conscious intention to move T normally occurred too late to be the cause of movement genesis. See the example of a subject's graph below on the right. Although it is not shown on the graph, the subject's readiness potentials (ERP) tells us that his actions start at -2.8 seconds, and yet this is substantially earlier than his conscious intention to move, time "T" (-1.8 seconds). Matsuhashi and Hallet concluded that the feeling of the conscious intention to move does not cause movement genesis; both the feeling of intention and the movement itself are the result of unconscious processing. [20]

The rationale

A simple "signalling noise" is used, but it is to warn participants that they must prevent any actions they are aware of.

This study is similar to Libet's in some ways: volunteers were again asked to perform finger extensions in short, self-paced intervals. In this version of the experiment, researchers introduced randomly timed “stop tones” during the self paced movements. If participants were not conscious of any intention to move, they simply ignored the tone. On the other hand, if they were aware of their intention to move at the time of the tone, they had to try to veto the action, then relax for a bit before continuing self-paced movements. This experimental design allowed Matsuhashi and Hallet to see when, once the subject moved their finger, any tones occurred. The goal was to identify their own equivalent of Libet’s W, their own estimation of the timing of the conscious intention to move, which they would call “T”.

Testing the hypothesis that 'conscious intention occurs after movement genesis has already begun' required the researchers to analyse the distribution of tones before actions. The idea is that, after time T, tones will lead to vetoing and thus a reduced representation in the data. There would also be a point of no return P where a tone was too close to the movement onset for the movement to be vetoed. In other words, the researchers were expecting to see the following on the graph: many tones (while the subjects are not yet aware of their movement genesis), followed by a drop in the number of tones during a certain period of time (while the subjects are conscious of their intentions and are stopping any movements), and finally a brief increase again in tones (when the subjects do not have the time to process the tone and prevent an action - they have past the action's "point of no return"). That is exactly what the researchers found (see the graph on the right, below).

Graphing tones as they appeared (or didn't) in the time before any action. In this case, researchers believe the subject becomes aware of his/her actions at about -1.769 seconds (this is time 'T'). A typical, strange example: not shown here are this subject's ERP recordings, which suggest movement preparation as early as −2.8 seconds.

Take one volunteer, for instance. The graph shows the times at which tones occurred when the volunteer moved. He or she showed many tones on average up until 1.8 seconds before movement onset, but a significant decrease in tones immediately after that time. Presumably this is because the subject usually became aware of his or her intention to move at about -1.8 seconds, which is then labelled point T. Since most actions are vetoed if a tone occurs after point T, there are very few tones represented during that range. Finally, there is a sudden increase in the number of tones appearing before an action at -0.1 seconds: meaning this subject has passed point P. Matsuhashi and Hallet were thus able to establish an average time T (−1.8 seconds) without subjective report. This, they compared to ERP measurements of movement (which detected movement beginning at about −2.8 seconds on average for this participant). In the end, since T — like Libet’s original W — was often found after movement genesis had already begun, the authors concluded that the generation of awareness occurs afterwards or in parallel to action, but most importantly, it is probably not the cause.[20]

Criticisms

Haggard describes other studies at the neuronal levels as providing "a reassuring confirmation of previous studies that recorded neural populations"[1] such as the one just described. Note that these results were gathered using finger movements, and may not necessarily generalize to other actions such as thinking, or even other motor actions in different situations. Indeed, the human act of planning has implications for free will and so this ability must also be explained by any theories of unconscious decision making. Philosopher Alfred Mele also doubts the conclusions of these studies. He explains that simply because a movement may have been initiated before our "conscious self" has become aware of it does not mean our consciousness does not still get to approve, modify, and perhaps cancel (called vetoing) the action. [21]

Manipulating the unconscious

Transcranial magnetic stimulation uses magnetism to safely stimulate or inhibit parts of the brain.

Related experiments showed that neurostimulation could affect which hands people move, even though the experience of free will was intact. Ammon and Gandevia found that it was possible to influence which hand people move by stimulating frontal regions that are involved in movement planning using transcranial magnetic stimulation in either the left or right hemisphere of the brain.[22]

Scientists were able to change which hand subjects normally chose to move without subjects noticing the influence.

Right-handed people would normally choose to move their right hand 60% of the time, but when the right hemisphere was stimulated they would instead choose their left hand 80% of the time (recall that the right hemisphere of the brain is responsible for the left side of the body, and the left hemisphere for the right). Despite the external influence on their decision-making, the subjects continued to report that they believed their choice of hand had been made freely. In a follow-up experiment, Alvaro Pascual-Leone and colleagues found similar results, but also noted that the transcranial magnetic stimulation must occur within 200 milliseconds, consistent with the time-course derived from the Libet experiments.[23]

It should be noted that, despite his findings, Libet himself did not interpret his experiment as evidence of the inefficacy of conscious free will - he points out that although the tendency to press a button may be building up for 500 milliseconds, the conscious will retains a right to veto any action at the last moment.[24] According to this model, unconscious impulses to perform a volitional act are open to suppression by the conscious efforts of the subject (sometimes referred to as "free won't"). A comparison is made with a golfer, who may swing a club several times before striking the ball. The action simply gets a rubber stamp of approval at the last millisecond. Max Velmans argues however that "free won't" may turn out to need as much neural preparation as "free will" (see below).[25]

Unconsciously cancelling actions

The possibility that human "free won't" is also the prerogative of the subconscious is being explored.

Retrospective judgement of free choice

As green light switches to yellow, research seems to suggest that humans cannot tell the difference between "deciding" to keep driving, and having no time to decide at all.

Recent research by Simone Kühn and Marcel Brass suggests that our consciousness may not be what causes some actions to be vetoed at the last moment. First of all, their experiment relies on the simple idea that we ought to know when we consciously cancel an action (i.e. we should have access to that information ). Secondly, they suggest that access to this information means humans should find it easy to tell, just after completing an action, whether it was impulsive (there being no time to decide) and when there was time to deliberate (the participant decided to allow/not to veto the action). The study found evidence that subjects could not tell this important difference. This again leaves some conceptions of free will vulnerable to the introspection illusion. The researchers interpret their results to mean that the decision to "veto" an action is determined subconsciously, just as the initiation of the action may have been subconscious in the first place.[26]

The experiment

The experiment involved asking volunteers to respond to a go-signal by pressing an electronic "go" button as quickly as possible.[26] In this experiment the go-signal was represented as a visual stimulus shown on a monitor (e.g. a green light as shown on the picture). The participants' reaction times (RT) were gathered at this stage, in what was described as the "primary response trials".

The primary response trials were then modified, in which 25% of the go-signals were subsequently followed by an additional signal - either a “stop” or “decide” signal. The additional signals occurred after a "signal delay" (SD), a random amount of time up to 2 seconds after the initial go-signal. They also occurred equally, each representing 12.5% of experimental cases. These additional signals were represented by the initial stimulus changing colour (e.g. to either a red or orange light). The other 75% of go-signals were not followed by an additional signal - and was therefore considered the "default" mode of the experiment. The participants' task of responding as quickly as possible to the initial signal (i.e. pressing the "go" button) remained.

Upon seeing the initial go-signal, the participant would immediately intend on pressing the "go" button. The participant was instructed to cancel their immediate intention to press the "go" button if they saw a stop signal. The participant was instructed to select randomly (at their leisure) between either pressing the "go" button, or not pressing it, if they saw a decide signal. Those trials in which the decide signal was shown after the initial go-signal ("decide trials"), for example, required that the participants prevent themselves from acting impulsively on the initial go-signal and then decide what to do. Due to the varying delays, this was sometimes impossible (e.g. some decide signals simply appeared too late in the process of them both intending to and pressing the go button for them to be obeyed).

Those trials in which the subject reacted to the go-signal impulsively without seeing a subsequent signal show a quick RT of about 600ms. Those trials in which the decide signal was shown too late, and the participant had already enacted their impulse to press the go-button (i.e. had not decided to do so), also show a quick RT of about 600ms. Those trials in which a stop signal was shown and the participant successfully responded to it, do not show a response time. Those trials in which a decide signal was shown, and the participant decided not to press the go-button, also do not show a response time. Those trials in which a decide signal was shown, and the participant had not already enacted their impulse to press the go-button, but (in which it was theorised that they) had had the opportunity to decide what to do, show a comparatively slow RT, in this case closer to 1400ms.[26].

The participant was asked at the end of those "decide trials" in which they had actually pressed the go-button whether they had acted impulsively (without enough time to register the decide signal before enacting their intent to press the go-button in response to the initial go-signal stimulus), or had acted based upon a conscious decision made after seeing the decide signal. Based upon the response time data however, it appears there was discrepancy between when the user thought they had had the opportunity to decide (and had therefore not acted on their impulses) - in this case deciding to press the go-button, and when they thought they had acted impulsively (based upon the initial go-signal) - where the decide signal came too late to be obeyed.

The rationale

Kuhn and Brass wanted to test participant self-knowledge. The first step was that after every decide trial, participants were next asked whether they had actually had time to decide. Specifically, the volunteers were asked to label each decide trial as either failed-to-decide (the action was the result of acting impulsively on the initial go-signal) or successful decide (the result of a deliberated decision). See the diagram on the right for this decide trial split: failed-to-decide and successful decide; the next split in this diagram (participant correct or incorrect) will be explained at the end of this experiment. Note also that the researchers sorted the participants’ successful decide trials into “decide go” and “decide nogo”, but were not concerned with the nogo trials since they did not yield any RT data (and are not featured anywhere in the diagram on the right). Note that successful stop trials did not yield RT data either.

The different types of trials and their different possible outcomes.

Kuhn and Brass now knew what to expect: primary response trials, any failed stop trials, and the “failed-to-decide” trials were all instances where the participant obviously acted impulsively – they would show the same quick RT. In contrast, the “successful decide” trials (where the decision was a “go” and the subject moved) should show a slower RT. Presumably, if deciding whether to veto is a conscious process, volunteers should have no trouble distinguishing impulsivity from instances of true deliberate continuation of a movement. Again, this is important since decide trials require that participants rely on self knowledge. Note that stop trials cannot test self knowledge because if the subject does act, it is obvious to them that they reacted impulsively.[26]

Results and implications

The general distribution of reaction times for the different trials. Notice the timing of the two peaks for trials labelled "successful decide".

Unsurprisingly, the recorded RTs for the primary response trials, failed stop trials, and “failed-to-decide” trials all showed similar RTs: 600ms seems to indicate an impulsive action made without time to truly deliberate. What the two researchers found next was not as easy to explain: while some “successful decide” trials did show the tell-tale slow RT of deliberation (averaging around 1400ms), participants had also labelled many impulsive actions as “successful decide”. This result is startling because participants should have had no trouble identifying which actions were the results of a conscious “I will not veto”, and which actions were un-deliberated, impulsive reactions to the initial go-signal. As the authors explain:

[The results of the experiment] clearly argue against Libet’s assumption that a veto process can be consciously initiated. He used the veto in order to reintroduce the possibility to control the unconsciously initiated actions. But since the subjects are not very accurate in observing when they have [acted impulsively instead of deliberately], the act of vetoing cannot be consciously initiated.[26]

In decide trials the participants, it seems, were not able to reliably identify whether they had actually had time to decide – at least, not based on internal signals. The authors explain that this result is difficult to reconcile with the idea of a conscious veto, but simple to understand if the veto is considered an unconscious process.[26] Thus it seems that the intention to move might not only arise from the subconscious, but it may only be inhibited if the subconscious says so. This conclusion could suggest that the phenomenon of "consciousness" is more of narration than direct arbitration (i.e. unconscious processing causes all thoughts, and these thoughts are again processed subconsciously).

Criticisms

In this recent experiment, subjects could not reliably distinguish between "producing an action without stopping and stopping an action before voluntarily resuming".[26] The conclusions that are drawn from this information, however - such as the assumption that only the faster decisions can be unconscious and that because the conscious ones have the same timing they must also be unconscious - have yet to be debated properly or even replicated. It is also worth noting that Libet consistently referred to a veto of an action that was initiated endogenously.[24] That is, a veto that occurs in the absence of external cues, instead relying on only internal cues (if any at all). This veto may be a different type of veto than the one explored by Kühn and Brass using their decide signal.

Other related phenomena

Retrospective construction

The idea behind retrospective construction is that, while part of the "yes, I did it" feeling of agency seems to occur during action, there also seems to be processing performed after the fact - after the action is performed - to establish the full feeling of agency.[27] Unconscious agency processing can even alter, in the moment, how we perceive the timing of sensations or actions. [28] [29] Kühn and Brass apply retrospective construction to explain the two peaks in "successful decide" RT's. They suggest that the late decide trials were actually deliberated, but that the impulsive early decide trials that should have been labelled "failed to decide" were mistaken during unconscious agency processing. They say that people "persist in believing that they have access to their own cognitive processes" when in fact we do a great deal of automatic unconscious processing before conscious perception occurs.

Related models

Neurological disorders such as alien hand syndrome make a person lose his sense of agency.

The idea that intention co-occurs (rather than causes) movement is reminiscent of "forward models of motor control" (or FMMC, which have been used to try to explain inner speech). FMMCs describe parallel circuits: movement is processed in parallel with other predictions of movement; if the movement matches the prediction - the feeling of agency occurs. FMMCs have been applied in other related experiments. Metcalfe and her colleagues used an FMMC to explain how volunteers determine whether they are in control of a computer game task. On the other hand, they acknowledge other factors too. The authors attribute feelings of agency to desirability of the results (see self serving biases) and top-down processing (reasoning and inferences about the situation).[30]

In this case, it is by the application of the forward model that one might imagine how other consciousness processes could be the result of efferent, predictive processing. If the conscious self is the efferent copy of actions and vetoes being performed, then the consciousness is a sort of narrator of what is already occurring in the body, and an incomplete narrator at that. Haggard, summarizing data taken from recent neuron recordings, says "these data give the impression that conscious intention is just a subjective corollary of an action being about to occur".[1][2] Parallel processing helps explain how we might experience a sort of contra-causal free will even if it were determined.

How the brain constructs consciousness is still a mystery, and cracking it open would have a significant bearing on the question of free will. Numerous different models have been proposed, for example, the Multiple Drafts Model which argues that there is no central Cartesian theater where conscious experience would be represented, but rather that consciousness is located all across the brain. This model would explain the delay between the decision and conscious realization, as experiencing everything as a continuous 'filmstrip' comes behind the actual conscious decision. In contrast, there exist models of Cartesian materialism that have gained recognition by neuroscience, implying that there actually might be special brain areas that store the contents of consciousness; this does not, however, rule out the possibility of a conscious will. Other models such as epiphenomenalism argue that conscious will is an illusion, and that consciousness is a by-product of physical states of the world. Work in this sector is still highly speculative, and there is no single model of consciousness which would be favored by the researchers. (See also: Philosophy of mind.)

Although humans clearly make choices, the role of consciousness (at least, when it comes to motor movements) may need re-conceptualization. Only one thing is certain: the correlation of a conscious "intention to move" with a subsequent "action" does not guarantee causation. Recent studies cast doubt on such a causal relation, and so more empirical data is required.

The pre-SMA and the intention to move

Scanning the brain in action, the readiness potential that indicates the beginning of movement genesis is recorded by an EEG applied to the pre-supplementary motor area (pre-SMA) of the brain. Directly stimulating the pre-SMA causes volunteers to report a feeling of intention, and sufficient stimulation of that same area causes physical movement.[31] This suggests that awareness of an intention to move may literally be the “sensation” of the body’s early movement, but certainly not the cause. Other studies have at least suggested that "The greater activation of the SMA, SACC, and parietal areas during and after execution of internally generated actions suggests that an important feature of internal decisions is specific neural processing taking place during and after the corresponding action. Therefore, awareness of intention timing seems to be fully established only after execution of the corresponding action, in agreement with the time course of neural activity observed here."[32]

More recent studies using electrodes and scanning the brain more directly have yielded further insights.[2][clarification needed]

See also

  • Thought identification, through the use of technology

References

  1. ^ a b c Haggard, Patrick.(2011). Decision Time for Free Will. Neuron, 69
  2. ^ a b c d e Fried, I., Mukamel, R., and Kreiman, G. (2011). Neuron 69, this issue, 548–562.
  3. ^ Soon, C.; Brass, M.; Heinze, H.; Haynes, J. (2008). "Unconscious determinants of free decisions in the human brain.". Nature neuroscience 11 (5): 543–545. doi:10.1038/nn.2112. PMID 18408715.  edit
  4. ^ "The Moral Landscape", pg. 112
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