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Implicate order and explicate order are ontological concepts for quantum theory coined by theoretical physicist David Bohm during the early 1980s. They are used to describe two different frameworks for understanding the same phenomenon or aspect of reality. In particular, the concepts were developed in order to explain the bizarre behaviors of subatomic particles which quantum physics describes and predicts with elegant precision but struggles to explain.[1]

In Bohm's Wholeness and the Implicate Order, he used these notions to describe how the appearance of such phenomena might appear differently, or might be characterized by, varying principal factors, depending on contexts such as scales.[2] The implicate (also referred to as the "enfolded") order is seen as a deeper and more fundamental order of reality. In contrast, the explicate or "unfolded" order includes the abstractions that humans normally perceive. As he wrote:

In the enfolded [or implicate] order, space and time are no longer the dominant factors determining the relationships of dependence or independence of different elements. Rather, an entirely different sort of basic connection of elements is possible, from which our ordinary notions of space and time, along with those of separately existent material particles, are abstracted as forms derived from the deeper order. These ordinary notions in fact appear in what is called the "explicate" or "unfolded" order, which is a special and distinguished form contained within the general totality of all the implicate orders (Bohm 1980, p. xv).

Overview

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The notion of implicate and explicate orders emphasizes the primacy of structure and process over individual objects. The latter are seen as mere approximations of an underlying process. In this approach, quantum particles and other objects are understood to have only a limited degree of stability and autonomy.[3]

Bohm believed that the weirdness of the behavior of quantum particles is caused by unobserved forces, maintaining that space and time might actually be derived from an even deeper level of objective reality. In the words of F. David Peat, Bohm considered that what we take for reality are "surface phenomena, explicate forms that have temporarily unfolded out of an underlying implicate order." That is, the implicate order is the ground from which reality emerges.[4]

The implicate order as an algebra

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Bohm, his colleague Basil Hiley, and other physicists of Birkbeck College worked toward a model of quantum physics in which the implicate order is represented in the form of an appropriate algebra or other pregeometry. They considered spacetime itself as part of an explicate order that is connected to an implicate order that they called pre-space. The spacetime manifold and the properties of locality and nonlocality all arise from an order in such pre-space. A. M. Frescura and Hiley suggested that an implicate order could be carried by an algebra, with the explicate order being contained in the various representations of this algebra.[5][6]

In analogy to Alfred North Whitehead's notion of "actual occasion,"[7] Bohm considered the notion of moment – a moment being a not entirely localizable event, with events being allowed to overlap [8] and being connected in an overall implicate order:[9]

I propose that each moment of time is a projection from the total implicate order. The term projection is a particularly happy choice here, not only because its common meaning is suitable for what is needed, but also because its mathematical meaning as a projection operation, P, is just what is required for working out these notions in terms of the quantum theory.

Bohm emphasized the primary role of the implicate order's structure:[10]

My attitude is that the mathematics of the quantum theory deals primarily with the structure of the implicate pre-space and with how an explicate order of space and time emerges from it, rather than with movements of physical entities, such as particles and fields. (This is a kind of extension of what is done in general relativity, which deals primarily with geometry and only secondarily with the entities that are described within this geometry.)

The explicate order and quantum entanglement

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Central to Bohm's schema are correlations between observables of entities which seem separated by great distances in the explicate order (such as a particular electron here on Earth and an alpha particle in one of the stars in the Abell 1835 galaxy, then a possible candidate for farthest galaxy from Earth known to humans), manifestations of the implicate order. Within quantum theory, there is entanglement of such objects.

This view of order necessarily departs from any notion which entails signalling, and therefore causality. The correlation of observables does not imply a causal influence, and in Bohm's schema, the latter represents 'relatively' independent events in spacetime; and therefore explicate order.

A common grounding for consciousness and matter

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Karl H. Pribram's research suggests that memories may not be localized in specific regions of brains

The implicate order represents the proposal of a general metaphysical concept in terms of which it is claimed that matter and consciousness might both be understood, in the sense that it is proposed that both matter and consciousness: (i) enfold the structure of the whole within each region, and (ii) involve continuous processes of enfoldment and unfoldment. For example, in the case of matter, entities such as atoms may represent continuous enfoldment and unfoldment which manifests as a relatively stable and autonomous entity that can be observed to follow a relatively well-defined path in spacetime. In the case of consciousness, Bohm pointed toward evidence presented by Karl Pribram that memories may be enfolded within every region of the brain rather than being localized (for example, in particular regions of the brain, cells, or atoms).

Bohm went on to say:

As in our discussion of matter in general, it is now necessary to go into the question of how in consciousness the explicate order is what is manifest ... the manifest content of consciousness is based essentially on memory, which is what allows such content to be held in a fairly constant form. Of course, to make possible such constancy it is also necessary that this content be organized, not only through relatively fixed association but also with the aid of the rules of logic, and of our basic categories of space, time, causality, universality, etc. ... there will be a strong background of recurrent, stable, and separable features, against which the transitory and changing aspects of the unbroken flow of experience will be seen as fleeting impressions that tend to be arranged and ordered mainly in terms of the vast totality of the relatively static and fragmented content of [memories].[11]

Bohm also claimed that "as with consciousness, each moment has a certain explicate order, and in addition it enfolds all the others, though in its own way. So the relationship of each moment in the whole to all the others is implied by its total content: the way in which it 'holds' all the others enfolded within it." Bohm characterises consciousness as a process in which at each moment, content that was previously implicate is presently explicate, and content which was previously explicate has become implicate.

One may indeed say that our memory is a special case of the process described above, for all that is recorded is held enfolded within the brain cells and these are part of matter in general. The recurrence and stability of our own memory as a relatively independent sub-totality is thus brought about as part of the very same process that sustains the recurrence and stability in the manifest order of matter in general. It follows, then, that the explicate and manifest order of consciousness is not ultimately distinct from that of matter in general.[12]

Analogies

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Ink droplet analogy

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Bohm also used the term unfoldment to characterise processes in which the explicate order becomes relevant (or "relevated"). Bohm likens unfoldment also to the decoding of a television signal to produce a sensible image on a screen. The signal, screen, and television electronics in this analogy represent the implicate order, while the image produced represents the explicate order. He also uses an example in which an ink droplet can be introduced into a highly viscous substance (such as glycerine), and the substance rotated very slowly, such that there is negligible diffusion of the substance. In this example, the droplet becomes a thread, which in turn eventually becomes invisible. However, by rotating the substance in the reverse direction, the droplet can essentially reform. When it is invisible, according to Bohm, the order of the ink droplet as a pattern can be said to be implicate within the substance.

In another analogy, Bohm asks us to consider a pattern produced by making small cuts in a folded piece of paper and then, literally, unfolding it. Widely separated elements of the pattern are, in actuality, produced by the same original cut in the folded piece of paper. Here, the cuts in the folded paper represent the implicate order, and the unfolded pattern represents the explicate order.

Holograms and implicate order

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See also: Holographic principle and Holographic paradigm
In a holographic reconstruction, each region of a photographic plate contains the whole image

Bohm employed the hologram as a means of characterising implicate order, noting that each region of a photographic plate in which a hologram is observable contains within it the whole three-dimensional image, which can be viewed from a range of perspectives. That is, each region contains a whole and undivided image. In Bohm's words:

There is the germ of a new notion of order here. This order is not to be understood solely in terms of a regular arrangement of objects (e.g., in rows) or as a regular arrangement of events (e.g., in a series). Rather, a total order is contained, in some implicit sense, in each region of space and time. Now, the word 'implicit' is based on the verb 'to implicate'. This means 'to fold inward' ... so we may be led to explore the notion that in some sense each region contains a total structure 'enfolded' within it".[13]

Bohm noted that, although the hologram conveys undivided wholeness, it is nevertheless static.

In this view of order, laws represent invariant relationships between explicate entities and structures, and thus Bohm maintained that, in physics, the explicate order generally reveals itself within well-constructed experimental contexts as, for example, in the sensibly observable results of instruments. With respect to implicate order, however, Bohm asked us to consider the possibility instead "that physical law should refer primarily to an order of undivided wholeness of the content of description similar to that indicated by the hologram rather than to an order of analysis of such content into separate parts...".[14]

Implicate order in art

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In the work Science, Order, and Creativity (Bohm and Peat, 1987), examples of implicate orders in science are laid out, as well as implicate orders which relate to painting, poetry and music.

Bohm and Peat emphasize the role of orders of varying complexity, which influence the perception of a work of art as a whole. They note that implicate orders are accessible to human experience. They refer, for instance, to earlier notes which reverberate when listening to music, or various resonances of words and images which are perceived when reading or hearing poetry.

Christopher Alexander discussed his work in person with Bohm, and pointed out connections among his work and Bohm's notion of an implicate order in The Nature of Order.[15]

Bohm features as a fictional character in the novel The Wave by British author Lochlan Bloom. The novel includes multiple narratives and explores many of the concepts of Bohm's work on implicate and explicate orders.[16]

Challenges to some generally prevailing views

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In proposing this new notion of order, Bohm explicitly challenged a number of tenets that he believed are fundamental to much scientific work:

  1. that phenomena are reducible to fundamental particles and laws describing the behaviour of particles, or more generally to any static (i.e., unchanging) entities, whether separate events in spacetime, quantum states, or static entities of some other nature;
  2. related to (1), that human knowledge is most fundamentally concerned with mathematical prediction of statistical aggregates of particles;
  3. that an analysis or description of any aspect of reality (e.g., quantum theory, the speed of light) can be unlimited in its domain of relevance;
  4. that the Cartesian coordinate system, or its extension to a curvilinear system, is the deepest conception of underlying order as a basis for analysis and description of the world;
  5. that there is ultimately a sustainable distinction between reality and thought, and that there is a corresponding distinction between the observer and observed in an experiment or any other situation (other than a distinction between relatively separate entities valid in the sense of explicate order); and
  6. that it is, in principle, possible to formulate a final notion concerning the nature of reality, i.e., a Theory of Everything.
A hydrogen atom and its constituent particles: an example of an over-simplified way of looking at a small collection of posited building blocks of the universe

Bohm's proposals have at times been dismissed largely on the basis of such tenets. His paradigm is generally opposed to reductionism, and some view it as a form of ontological holism. On this, Bohm noted of prevailing views among physicists that "the world is assumed to be constituted of a set of separately existent, indivisible, and unchangeable 'elementary particles', which are the fundamental 'building blocks' of the entire universe ... there seems to be an unshakable faith among physicists that either such particles, or some other kind yet to be discovered, will eventually make possible a complete and coherent explanation of everything" (Bohm 1980, p. 173).

In Bohm's conception of order, primacy is given to the undivided whole, and the implicate order inherent within the whole, rather than to parts of the whole, such as particles, quantum states, and continua. This whole encompasses all things, structures, abstractions, and processes, including processes that result in (relatively) stable structures as well as those that involve a metamorphosis of structures or things. In this view, parts may be entities normally regarded as physical, such as atoms or subatomic particles, but they may also be abstract entities, such as quantum states. Whatever their nature and character, according to Bohm, these parts are considered in terms of the whole, and in such terms, they constitute relatively separate and independent "sub-totalities." The implication of the view is, therefore, that nothing is fundamentally separate or independent.

Bohm 1980, p. 11, said: "The new form of insight can perhaps best be called Undivided Wholeness in Flowing Movement. This view implies that flow is in some sense prior to that of the ‘things’ that can be seen to form and dissolve in this flow." According to Bohm, a vivid image of this sense of analysis of the whole is afforded by vortex structures in a flowing stream. Such vortices can be relatively stable patterns within a continuous flow, but such an analysis does not imply that the flow patterns have any sharp division, or that they are literally separate and independently existent entities; rather, they are most fundamentally undivided. Thus, according to Bohm’s view, the whole is in continuous flux, and hence is referred to as the holomovement (movement of the whole).

Quantum theory and relativity theory

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A key motivation for Bohm in proposing a new notion of order was the well-known incompatibility of quantum theory with relativity theory. Bohm 1980, p. xv summarised the state of affairs he perceived to exist:

...in relativity, movement is continuous, causally determinate and well defined, while in quantum mechanics it is discontinuous, not causally determinate and not well-defined. Each theory is committed to its own notions of essentially static and fragmentary modes of existence (relativity to that of separate events connectible by signals, and quantum mechanics to a well-defined quantum state). One thus sees that a new kind of theory is needed which drops these basic commitments and at most recovers some essential features of the older theories as abstract forms derived from a deeper reality in which what prevails is unbroken wholeness.

Bohm maintained that relativity and quantum theories are in basic contradiction in these essential respects, and that a new concept of order should begin with that toward which both theories point: undivided wholeness. This should not be taken to mean that he advocated such powerful theories be discarded. He argued that each was relevant in a certain context—i.e., a set of interrelated conditions within the explicate order—rather than having unlimited scope, and that apparent contradictions stem from attempts to overgeneralize by superposing the theories on one another, implying greater generality or broader relevance than is ultimately warranted. Thus, Bohm 1980, pp. 156–167 argued: "... in sufficiently broad contexts such analytic descriptions cease to be adequate ... 'the law of the whole' will generally include the possibility of describing the 'loosening' of aspects from each other, so that they will be relatively autonomous in limited contexts ... however, any form of relative autonomy (and heteronomy) is ultimately limited by holonomy, so that in a broad enough context such forms are seen to be merely aspects, relevated in the holomovement, rather than disjoint and separately existent things in interaction."

Hidden variable theory

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Before developing his implicit order approach, Bohm had proposed a hidden variable theory of quantum physics (see Bohm interpretation). According to Bohm, a key motivation for doing so had been purely to show the possibility of such theories. On this, Bohm 1980, p. 81 said, "... it should be kept in mind that before this proposal was made there had existed the widespread impression that no conception of any hidden variable at all, not even if it were abstract and hypothetical, could possibly be consistent with the quantum theory." Bohm 1980, p. 110 also claimed that "the demonstration of the possibility of theories of hidden variables may serve in a more general philosophical sense to remind us of the unreliability of conclusions based on the assumption of the complete universality of certain features of a given theory, however general their domain of validity seems to be." Another aspect of Bohm's motivation had been to point out a confusion he perceived to exist in quantum theory. On the dominant approaches in quantum theory, he said: "...we wish merely to point out that this whole line of approach re-establishes at the abstract level of statistical potentialities the same kind of analysis into separate and autonomous components in interaction that is denied at the more concrete level of individual objects" (Bohm 1980, p. 174).

See also

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References

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Implicate and explicate order

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The implicate and explicate order are foundational ontological concepts in quantum theory developed by theoretical physicist to articulate the holistic nature of as an undivided whole. The implicate order denotes a primary, enfolded level of where all elements interpenetrate and are implicitly contained within each region of space and time, transcending conventional notions of separation. In contrast, the explicate order represents the secondary, unfolded manifestation of this deeper , appearing as distinct, stable entities and events in ordinary space-time that align with classical perceptions and measurements. Bohm introduced these ideas in his 1980 book , proposing them as a response to the limitations of traditional , which he viewed as overly fragmented and unable to capture the underlying unity of the universe. At the core of the implicate order lies the concept of holomovement, an unbroken flux of total activity where space and time are not dominant factors in determining interconnections, allowing for phenomena like quantum non-locality where distant particles influence each other instantaneously. Bohm illustrated this enfoldment through analogies such as the hologram, in which the entire image is encoded within every part of the interference pattern, or ink droplets dispersed in a viscous , where the drops can be "enfolded" into a uniform mass and later "unfolded" to reveal their original form. The explicate order emerges as a special, abstracted case from the implicate order, functioning like relatively invariant patterns—such as vortices in a flowing stream—that seem independent but derive from the total movement. This framework extends beyond physics to encompass , , and even social structures, suggesting that fragmented thinking in science and mirrors the of separateness in the explicate order. Bohm argued that recognizing the primacy of the implicate order could unify matter, life, and mind, offering a new basis for understanding not as fixed substances but as processes within a universal flux.

Historical and Conceptual Background

Origins in Bohm's Work

, born on December 20, 1917, in Wilkes-Barre, Pennsylvania, developed a profound interest in physics during his undergraduate studies at Pennsylvania State College and later pursued graduate work at the and the , where he earned his PhD in 1943 under . Influenced by Oppenheimer's mentorship and subsequent interactions with during his time as an assistant professor at from 1947 to 1951, Bohm explored foundational issues in , including hidden variables theories. His career was disrupted by the McCarthy-era anti-communist investigations; unwilling to testify before the in 1950, Bohm faced indictment and left the in 1951, eventually settling in the after stints in and , where he continued his research at Birkbeck College, . In the 1950s, Bohm advanced a deterministic interpretation of through his 1952 pilot-wave theory, rediscovering and extending Louis de Broglie's earlier ideas by incorporating hidden variables to address non-locality and particle trajectories. Bohm's concepts of implicate and explicate order evolved from this quantum foundation into a broader ontological framework emphasizing and undivided wholeness. During the 1970s, through seminars and dialogues at Birkbeck College, Bohm refined these ideas, critiquing fragmentation in scientific thought and exploring the unity of matter and consciousness; this period included key publications like his 1976 essay "Fragmentation and Wholeness" and papers in Foundations of Physics (1971, 1973) that laid groundwork for non-local quantum processes. Influenced by ongoing conversations with philosopher starting in the late 1960s, Bohm integrated insights on the nature of mind and matter, viewing thought as a material process within a . These developments culminated in his seminal 1980 book, , where he fully articulated the implicate order as an enfolded, holistic structure underlying the explicate order of apparent , extending his earlier quantum work into a comprehensive metaphysical vision. In the 1980s, Bohm further extended these ideas through collaborations, notably with physicist F. David Peat, whose dialogues beginning in 1971 informed their 1987 co-authored book, Science, Order, and , which applied implicate order principles to , scientific , and societal structures while building directly on the 1980 framework. This evolution marked a shift from Bohm's initial focus on hidden variables in to an ontological extension incorporating , where the implicate order provides a deeper, generative reality beyond fragmented explicate manifestations.

Relation to Quantum Mechanics

The Copenhagen interpretation of quantum mechanics, dominant since the , posits that the act of observation collapses the wave function, introducing an inherent observer-dependence that renders quantum outcomes probabilistic and indeterminate until measurement occurs. This view exacerbates paradoxes like the Einstein-Podolsky-Rosen (EPR) of 1935, which highlighted non-locality in entangled particles, suggesting "spooky " that challenges classical notions of locality and separability without complete hidden variables. critiqued these elements as symptoms of an incomplete theory, arguing that they stem from analyzing quantum phenomena in terms of separable parts rather than an underlying undivided wholeness. In response, Bohm proposed a deterministic alternative in his 1952 papers, reviving Louis de Broglie's 1927 pilot-wave theory through a causal interpretation featuring hidden variables that guide particle trajectories via a quantum potential derived from the wave function. This approach restores and at a deeper level, though it is non-local, where apparent quantum arises from ignorance of these sub-quantum variables, and the implicate order serves as the enfolded, holistic reality from which the explicate order—the observed particle positions and momenta—unfolds deterministically. By treating the wave function as a real guiding field, Bohm's framework eliminates the need for observer-induced , positioning the implicate order as the ontological ground that resolves the probabilistic veil of standard . Central to this relation is Bohm's reconceptualization of non-locality, not as paradoxical action but as a natural manifestation of undivided wholeness in the implicate order, where distant elements remain interconnected through enfoldment rather than separation in space-time. The explicate order emerges as a projection or "unfolding" from this deeper implicate structure, akin to how a hologram encodes the whole in every part, thereby addressing EPR correlations without invoking influences. This ontological extension posits as indicative of a more fundamental reality beyond the explicate manifestations, where "the observing instrument is not separable from what is observed." Bohm's leftist associations led to investigations by the , his indictment, loss of his Princeton position, and departure from the United States in 1951, affecting his career. Despite this, the reception of his 1952 formulation was poor, primarily due to the dominance of the and low status of research, though it laid groundwork for later developments in , influencing ongoing debates on hidden variables and .

Core Concepts

The Implicate Order

The implicate order, introduced by physicist in his ontological framework for quantum theory, constitutes a fundamental level of reality characterized by enfoldment, in which the entire is interconnected as a seamless, holistic whole that precedes the distinctions of space, time, and separate entities. In this order, all phenomena are implicitly contained within one another, forming a deeper structure where ordinary notions of locality and independence do not apply, as space and time cease to be the primary factors governing relationships between elements. Key properties of the implicate order include its nature as an undivided totality, emphasizing potentiality rather than actuality, and a perpetual state of flux devoid of fixed or isolated parts. Bohm described this as a realm where "everything is enfolded into everything," highlighting the absence of fragmentation and the priority of dynamic flow over static forms. This flux represents the essence of reality, with change and movement underlying all existence, as "not only is everything changing, but all is flux." Ontologically, the implicate order functions as the primary ground of reality, from which the manifest explicate order unfolds as a secondary projection. It provides a coherent basis for quantum phenomena, exemplified by the quantum potential in Bohmian mechanics, which exerts a holistic, non-local influence on particle trajectories, guiding them through an interconnected web rather than local forces alone. This deeper structure thus underpins the apparent separateness of the observed world, serving as the ultimate source of both physical and informational content. Philosophically, the implicate order rejects the fragmentation of classical mechanistic views, proposing instead a non-fragmentary that aligns with insights from relativity and quantum theory while drawing inspiration from Eastern philosophical traditions, such as those emphasizing wholeness and interdependence. Bohm's framework, influenced by dialogues with , grounds this holistic perspective in physics, challenging Cartesian dualism and promoting an understanding of reality as an unbroken whole.

The Explicate Order

The explicate order, as articulated by physicist , constitutes the unfolded, manifest realm of reality wherein objects, events, and entities manifest as relatively autonomous and separate, positioned within distinct regions of space and time. This order forms the basis of everyday and classical , where phenomena can be analyzed into independent parts using Cartesian coordinates and quasi-rigid body approximations. In Bohm's framework, it represents the "content" of in its sensuous, analyzable form, abstracted from a deeper holistic process. The explicate order emerges through a selective projection or unfolding from the implicate order, functioning as a abstraction or intersection derived from a more general totality of enfolded potentialities. Bohm illustrates this derivation with the of a two-dimensional shadow projected from a three-dimensional object, or a facet revealing only a limited aspect of a higher-dimensional structure, thereby creating the appearance of fragmentation from an underlying unbroken flux. Examples of the explicate order abound in , where particles and waves are approximated as entities with well-defined trajectories, positions, and velocities, such as in the description of planetary orbits or streams composed of atoms. In quantum contexts, measurements serve to unfold latent possibilities from the implicate order into actual events within the explicate, as seen in the context-dependent manifestation of electrons as either particles or waves, governed by statistical patterns and principles like Heisenberg's uncertainty relation. Despite its utility in limited domains, the explicate order perpetuates an of inherent separateness among phenomena, which Bohm identifies as a root cause of fragmentation in scientific and broader societal thought. This perceptual obscures the fundamental wholeness of , rendering classical analytic methods inadequate for capturing quantum phenomena's undivided nature and necessitating a recognition of deeper interdependencies.

Holomovement and Unfolding Processes

The holomovement represents the foundational universal flux underlying both the implicate and explicate orders, conceived as an unbroken, undivided flowing movement that encompasses all of existence without beginning or end. In this view, reality is not composed of static substances but rather a dynamic where , , and all forms emerge as abstractions from an ongoing "movement of movement." Bohm describes it as the ground of all orders, akin to a flowing stream in which transient vortices—such as particles or events—arise and dissolve, illustrating the perpetual interweaving of elements across the totality of being. Central to the holomovement are the processes of enfolding and unfolding, through which the explicate order arises as a projection or from the deeper implicate order. Enfolding involves the totality being wrapped into a hidden, holistic structure within the implicate order, while unfolding projects specific, relatively stable forms into the manifest explicate order, as seen in everyday where sensory details from an underlying wholeness or in physical interactions like the of substances. This interplay is inherently reversible: just as a form can unfold from the implicate, it can refold back into it, emphasizing the fluid continuity rather than a one-way . The key mechanism driving this dynamic is the implicate totality, which contains all potentialities in an undifferentiated flux, with particular contexts or conditions selecting and actualizing specific configurations. Each region of the holomovement enfolds the entire structure, allowing for the of autonomous sub-totalities while preserving the underlying unity; for instance, stable patterns like organisms or thoughts manifest as recurrent abstractions from this comprehensive potential. This selection process ensures that the explicate order appears ordered and separable, yet it remains derivative of the implicate's infinite possibilities. The implications for change within the holomovement are that all phenomena—physical, mental, or —constitute temporary configurations in this ceaseless flux, challenging fragmented views of and promoting a holistic understanding of transformation. Rather than isolated events, changes arise as creative necessities from the total process, fostering insights into and action that align with the undivided movement, ultimately dissolving illusions of separation.

Mathematical and Physical Foundations

Implicate Order as an

The implicate order is conceptualized as a non-commutative , in which the elements encode enfolded potentials that underlie the holistic structure of reality, rather than isolated entities. This algebraic framework captures the interconnectedness of quantum processes, where operations do not commute, reflecting the inherent order of actions in the holomovement. In this structure, potentials are not manifest as explicit positions or momenta but as relational properties distributed across the entire system, emphasizing wholeness over fragmentation. A key development in formalizing this algebra is the pre-space approach advanced by Basil Hiley following David Bohm's foundational ideas, which posits an underlying algebraic process prior to the emergence of space-time. This pre-space algebra employs Clifford algebras to describe a holistic geometry, where geometric relations arise intrinsically from the algebra without presupposing a metric space. Specifically, for quantum systems, the Clifford algebra C(p,q)\mathcal{C}(p,q) over a real vector space with signature (p,q)(p,q) generates the necessary symmetries and dynamics; for instance, the Schrödinger particle is modeled in C(0,1)\mathcal{C}(0,1), the Pauli particle in C(3,0)\mathcal{C}(3,0), and the Dirac particle in C(1,3)\mathcal{C}(1,3). Elements within minimal left ideals of these algebras, such as the Clifford density element ρc=ΦLΦ~L\rho_c = \Phi_L \tilde{\Phi}_L, replace traditional wave functions and encode all quantum information holistically. The non-commutativity ensures that the enfolded order manifests as a process, with bilinear invariants of the first and second kinds yielding observable properties like probability densities and phase-related quantities. The basic algebraic structure incorporates tensor products to represent interconnections among enfolded elements, as in the generation of relations γiγj+γjγi=2gij1\gamma_i \otimes \gamma_j + \gamma_j \otimes \gamma_i = 2 g_{ij} \mathbf{1}, where γi\gamma_i are basis vectors and gijg_{ij} is the . These tensor products symbolize the relational web of the implicate order, allowing for the encoding of multi-particle correlations without classical separability. The dynamics are governed by equations such as the generalized in the algebra: itρc=[H,ρc]i \partial_t \rho_c = [H, \rho_c]_-, where HH is the Hamiltonian and [,][\cdot, \cdot]_- denotes the , ensuring evolution within the holistic framework. Central to this algebraic ontology is the quantum potential, which acts as a holistic guide influencing particle trajectories in the explicate order while originating from the implicate structure. In Bohmian mechanics, the wave function is expressed in polar form as ψ=Rexp(iS/)\psi = R \exp(i S / \hbar), where RR is the amplitude and SS the phase. Substituting into the time-dependent Schrödinger equation itψ=22m2ψ+Vψi \hbar \partial_t \psi = -\frac{\hbar^2}{2m} \nabla^2 \psi + V \psi yields two real equations upon separating real and imaginary parts. The imaginary part gives the continuity equation t( R2 )+(R2Sm)=0\partial_t (\ R^2\ ) + \nabla \cdot (R^2 \frac{\nabla S}{m}) = 0, describing probability conservation. The real part results in the modified Hamilton-Jacobi equation tS+(S)22m+V+Q=0\partial_t S + \frac{(\nabla S)^2}{2m} + V + Q = 0, where the quantum potential is Q=22m2RR.Q = -\frac{\hbar^2}{2m} \frac{\nabla^2 R}{R}. This QQ depends non-locally on the entire RR, embodying the implicate order's influence as a guiding field without local forces. The derivation highlights how QQ emerges from the algebraic enfoldment, providing a non-local interconnection that defies classical point-particle descriptions. Topological aspects of the implicate order are addressed through the non-commutative geometry inherent in Clifford algebras, which allow for configurations without reliance on classical points, facilitating descriptions of enfolded structures via algebraic invariants. This approach underscores the pre-geometric nature of the algebra, where topological features like rotational symmetries arise from the Clifford groupoid structure.

Explicate Order and Quantum Entanglement

In David Bohm's framework, quantum entanglement exemplifies how the explicate order manifests observable phenomena that appear non-local but arise from a deeper shared wholeness in the implicate order. Entangled particles, such as those in the Einstein-Podolsky-Rosen (EPR) setup, exhibit correlations that defy classical locality, yet Bohm interprets this as an unfolding of their prior enfoldment within an undivided holomovement, where distant events are interconnected through sub-quantum levels rather than signaling faster than light. Particles involved in entanglement are not independent entities but abstractions or projections from this enfolded totality, with their emerging from the overall quantum potential and of the implicate order. Upon , the explicate order actualizes specific states from this potential, revealing correlated outcomes as if the system "unfolds" a stable sub-totality while preserving the underlying non-separability. This process aligns with the for an entangled two-particle state, such as a maximally entangled : ψ=12(00+11)|\psi\rangle = \frac{1}{\sqrt{2}} \left( |00\rangle + |11\rangle \right)
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