Design Consciousness: The relationship between Plasmic, Fractal, Holographic and Quantum fields of EIM

 

Conceptual impressions surrounding this post have yet to be substantiated, corroborated, confirmed or woven into a larger argument, context or network. Objective: To generate symbolic links between scientific discovery, design awareness and consciousness.

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FIELD QUALITIES AND CHARACTERISTICS 

HOLOGRAPHIC = Modeled on information, pattern, distributed representation, contains information pattern of the whole, reflecting the “part-whole enfoldment”, information distributed where local changes can express nonlocal relationships, conveys the form of things rather than the energy through which forms manifest, 

PLASMIC = charge separation, fluidity, responsiveness to electro-magnetic forces, energetic medium underlying manifestation, “subtle matter”, “etheric”, continuous movement, turbulent, self-organizing currents, energetic, dynamic, subtle materiality, non-physical nature, interconnectivity, fluctuating dynamic structure, seen as source of energy, immense potential, unpredictable, creative, undifferentiated, dynamic change, unpredictable, inspiring, transformative 

FRACTAL = mathematical structures known for their self-similarity across different scales, repeat recursive patterns at various levels of magnification, each part of the structure mirrors the whole, maintain similar qualities regardless of the level in which they are examined, can generate incredibly complex and intricate forms mirroring the whole that can be extended to consciousness, scale invariance, complexity from simplicity, geometric order, inherent harmony, structure and predictability, natural formations and abstract concepts, simple iterative rules, symbolize universal patterns of harmony and order, ideas grow via repetition at different scales, allows for interconnection, recognition of individual elements no matter how small, 

 

QUANTUM 

1. Ontological Status: The Quantum Field as Fundamental Reality

In modern quantum field theory (QFT), fields - not particles - are ontologically primary. What are colloquially called "particles" are understood as localized excitations or quanta of underlying fields. Every fundamental particle type corresponds to a distinct quantum field permeating all of spacetime (e.g. electron field, quark fields, electromagnetic field.)

Key characteristics: fields exist everywhere in so-called "empty" space, matter is a manifestation of field excitation, not separate substance. Reality is continuous at the field level and discrete only in interaction.

This replaces classical substance metaphysics with a process-relational ontology.

2. Non-Locality and Entanglement

Quantum fields exhibit non-local correlations that cannot be reduced to classical spatial causation. When field excitations become entangled, their properties remain correlated regardless of distance.

Characteristics: information is encoded relationally, not locally, measurement collapses relational potential into definite outcomes, spatial separation does not imply energetic or informational separation.

This suggests that the quantum field behaves as a coherent whole, rather than an aggregate of independent parts.

3. Superposition and Virtual Potential 

At its core, the quantum field exists as a superposition of possible states. Prior to interaction or measurement, the field does not “decide” between alternatives. 

Qualities: Multiple states coexist as probability amplitudes. Reality is fundamentally modal (defined by what may occur). Determinacy emerges through interaction, not prior essence. This property directly supports interpretations of the quantum field as a field of virtual potential and probability, rather than fixed actuality.

4. Vacuum Fluctuation and Zero-Point Energy

Even in its lowest energy state (the vacuum), the quantum field is never inert. Due to the uncertainty principle, fields exhibit constant micro-fluctuations. 

Key traits: “Empty space” contains measurable energy. Virtual particles continuously appear and annihilate. The vacuum acts as an active generative substrate. 

This challenges classical notions of nothingness and aligns with metaphysical notions of plenum, aetheric substratum, or creative void. 

5. Probabilistic Causality (Non-Determinism) 

Quantum field behavior is intrinsically probabilistic, not merely epistemically uncertain. 

Characteristics: Outcomes are governed by probability distributions, not fixed trajectories. Causation is statistical rather than linear. Prediction concerns likelihoods, not certainties.

This introduces a design-relevant logic in which emergence replaces determinism and intention operates through constraint rather than command. 

6. Observer Participation and Measurement Sensitivity 

While interpretations vary, all viable quantum theories agree that measurement alters the field state. 

Relevant properties: Interaction defines outcome. The measuring apparatus becomes part of the system. Observation selects, rather than creates, reality. 

In philosophical terms, the quantum field is participatory, supporting frameworks where cognition, perception, or design intention are not external to reality but embedded within it. 

7. Relationality and Field Coupling 

Quantum fields do not exist in isolation; they interact, overlap, and modulate one another. 

Key qualities: Fields couple through fundamental forces. Properties arise from interaction, not intrinsic essence. Identity is relational, not absolute.

This undercuts classical object-based metaphysics and supports networked, systemic, and holographic interpretations of reality. 

8. Symmetry, Invariance, and Conservation 

Quantum fields are structured by symmetry principles, which govern conservation laws and allowable transformations. 

Characteristics: Gauge symmetries define force interactions. Symmetry breaking generates structure and differentiation. Laws of nature arise from invariance constraints. 

From a design-theoretic lens, symmetry acts as a generative grammar, while symmetry-breaking acts as creative differentiation. 

9. Temporality and Indeterminacy 

Time in quantum field theory is not always a simple linear parameter. Properties: Events are not strictly ordered until interaction. Causality can be frame-dependent. Temporal becoming is emergent rather than absolute. 

This aligns with process metaphysics, where time unfolds through events, not as a pre-existing container. 

10. Mathematical Abstractness and Symbolic Mediation 

The quantum field is accessible only through formal symbolic systems (operators, Hilbert spaces, path integrals). 

Implications: Reality is mediated through mathematical language. Measurement outcomes are symbolic translations of field behavior. Meaning arises through interpretation of form. 

This directly resonates with semiotic and design-consciousness models in which symbol, structure, and meaning co-emerge. 

11. Generativity and Emergence 

Finally, the quantum field is fundamentally creative. 

Qualities: New particles and structures emerge from fluctuations. Complexity arises from simple interaction rules. The macroscopic world is an emergent phenomenon. 

The quantum field thus functions as a generative substrate from which matter, energy, form, and information arise. 

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  Summary Table of Core Qualities 

   Domain           Quantum Field Characteristics 

Ontology            Fundamental, continuous, field-based

Causality            Probabilistic, non-deterministic 

Structure            Relational, non-local 

Dynamics           Fluctuating, generative 

Temporality        Event-based, emergent 

Epistemology     Observer-participatory 

Semiosis             Symbolically mediated 

Creativity            Emergent and self-organizing 

APA-Style References 

- Barad, K. (2007). Meeting the universe halfway: Quantum physics and the entanglement of matter and meaning. Duke University Press. 

- Dirac, P. A. M. (1930). The principles of quantum mechanics. Oxford University Press. 

- Heisenberg, W. (1958). Physics and philosophy: The revolution in modern science. Harper & Row. 

- Kaku, M. (1993). Quantum field theory: A modern introduction. Oxford University Press. 

- Penrose, R. (2004). The road to reality: A complete guide to the laws of the universe. Jonathan Cape. 

- Rovelli, C. (2016). Reality is not what it seems: The journey to quantum gravity. Riverhead Books. 

- Weinberg, S. (1995). The quantum theory of fields (Vols. 1–3). Cambridge University Press.

The author generated some of this text in part with GPT-4, OpenAI’s large-scale language-generation model. Upon generating draft language, the author reviewed, edited, and revised the language to their own liking and takes ultimate responsibility for the content of this publication

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"Design releases the soul through creation."

Edited: 

Find your truth. Know your mind. Follow your heart. Love eternal will not be denied. Discernment is an integral part of self-mastery. You may share this post on a non-commercial basis, the author and URL to be included. Please note … posts are continually being edited. All rights reserved. Copyright © 2025 C.G. Garant.