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| ai.viXra.org > Quantum Physics > 2505 |
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[30] ai.viXra.org:2505.0210 [pdf] submitted on 2025-05-31 21:18:07
Authors: Michael John Sarnowski
Comments: 21 Pages.
We develop a quantum field theory emerging from a discrete rotating substratum: the Holosphere lattice. Unlike traditional QFT built on continuous fields in smooth spacetime, this model treats angular phase coherence between nested, rotating spheres as the fundamental carrier of energy, force, and information. Canonical commutation relations, scalar and spinor field behavior, and vacuum excitations are derived from angular strain and quantized phase transitions between lattice units. A central prediction of this theory is the existence of a coherence horizon—a visibility limit beyond which light from faster-rotating outer regions becomes phase-incompatible with the observer’s local Holospheres. This results in an observational boundary not defined by distance, but by angular mismatch. The model naturally explains why the universe appears isotropic in all directions: every observer near the coherence boundary sees inward, toward slower coherent layers. The vacuum, in this framework, is not empty—it is structured, rotating, and memory-preserving. The lattice does not vanish. It spins. It becomes. It remembers.
Category: Quantum Physics
[29] ai.viXra.org:2505.0204 [pdf] submitted on 2025-05-30 01:21:16
Authors: Michael John Sarnowski
Comments: 7 Pages.
This paper presents a coherence-based model of quantum measurement and decoherence within the Holosphere lattice framework. We propose that measurement corresponds to the deterministic collapse of orbital phase alignment, triggered by interaction with structured regions of the lattice. These regions act as pointer states that destabilize propagating vacancy defects,leading to irreversible phase collapse into aligned angular modes. Decoherence arises fromthe statistical degradation of orbital coherence during these transitions, not from environmental entanglement, observer interaction, or wavefunction postulates. The model offers a local, causal, and physically grounded mechanism for classical outcomes emerging from coherent quantum dynamics.
Category: Quantum Physics
[28] ai.viXra.org:2505.0203 [pdf] submitted on 2025-05-30 01:24:21
Authors: Moninder Singh Modgil, Dnyandeo Patil
Comments: 13 Pages.
This paper investigates the interplay between two foundational quantum phenomena—Bell’s inequality violations and the Quantum Zeno Effect (QZE)—within the unified symmetry framework of the exceptional Lie group E8. We explore how frequent measurements applied to one particle in an entangled pair modify the entanglement correlations observed in Bell-type experiments, demonstrating that the QZEcan dynamically suppress transitions and affect the statistical outcomes of non-localmeasurements. Electroweak transitions modeled via the SU(2)L × U(1)Y symmetry are analyzed alongside flavor generation triality in the F4 subgroup of E8, revealing mechanisms by which Zeno-induced symmetry reduction may alter accessible Hilbert subspaces. The algebraic structure of E8 thus serves not only as a theoretical scaffold for unification but also as a fertile ground for simulating quantum informational processes such as projection-induced decoherence and entanglement modulation.
Category: Quantum Physics
[27] ai.viXra.org:2505.0201 [pdf] replaced on 2025-06-01 21:21:55
Authors: Iwl Robran
Comments: 9 Pages.
Bell-type experiments frequently contrast quantum predictions—particularly the cos²(φ) correlation curve—with a simplified "classical" benchmark that assumes linear decay in correlation with angular separation. This comparator, P_classical(φ) = 1 − (2φ/π), predicts 0.75 correlation at 22.5°, diverging from the quantum prediction of ≈0.85, and is used to claim that quantum mechanics violates classical expectations.This paper challenges the validity of that comparator.u2028We show that linear correlation decline cannot arise from smooth, localized classical fields. Using convolution and Fourier analysis on the circle, we prove that angular overlap between such fields must produce non-affine (curved) functions. The widely used linear benchmark is therefore not a physically realistic classical model—it is a construct of binary logic systems with stepwise transitions.We further argue that cos²(φ)-like correlation curves are a natural outcome of classical field overlap, not uniquely quantum. Bell’s framework may rule out binary hidden-variable theories, but it unfairly excludes a broad class of plausible field-based models.
Category: Quantum Physics
[26] ai.viXra.org:2505.0194 [pdf] submitted on 2025-05-29 01:56:35
Authors: Michael John Sarnowski
Comments: 23 Pages.
This paper introduces a Lagrangian formulation for Holosphere Theory, in which all physical phenomena arise from angular coherence strain in a discrete, rotating lattice of nested spheres. Energy, inertia, and force emerge from the directional propagation of Planck-scale vacancy defects that carry quantized angular strain through a cuboctahedral geometry. By treating angular coherence as a dynamical field, we construct an action principle based on strain minimization. The resulting variational framework provides a discrete analog to the Euler—Lagrange formalism, replacing continuum fields with lattice-based coherence gradients. We demonstrate how classical mechanics, relativistic curvature, quantum tunneling, and causal structure arise as limiting behaviors of strain propagation through this coherence lattice. This coherence Lagrangian represents a unifying structure for Holosphere dynamics and lays the foundation for future Hamiltonian and field-theoretic extensions.
Category: Quantum Physics
[25] ai.viXra.org:2505.0191 [pdf] submitted on 2025-05-29 01:45:42
Authors: Michael John Sarnowski
Comments: 3 Pages.
Quantum mechanics traditionally relies on complex-valued wavefunctions to describe phase,interference, and time evolution. However, in the Holosphere Theory—a discrete lattice modelcomposed of spinning, nested Planck-scale spheres—the imaginary component of the wavefunc-tion is reinterpreted as a physically real angular deviation from perfect radial coherence. This paper constructs a mathematical formulation of quantum dynamics using exclusively real-valued variables, replacing the imaginary unit i with 90-degree phase displacement operators derived from lattice coherence structure. We demonstrate that all standard quantum results, including interference, energy quantization, and probability currents, can be recovered from this real-coherence interpretation, offering a new ontological basis for the quantum world.
Category: Quantum Physics
[24] ai.viXra.org:2505.0190 [pdf] submitted on 2025-05-29 01:44:12
Authors: Anish Kumar
Comments: 4 Pages. (Note by ai.viXra.org Admin: Please cite listed sceintific references)
This paper proposes an alternative to traditional multiverse and block universe models. It introduces a theory where all possible timelines coexist within a single universal plane. Each timeline is accessible only to specific observers based on their entry point and trajectory. This model preserves causality within an observer's experience while accommodating a dynamically evolving past and future, addressing paradoxes such as retrocausality and historical modification.
Category: Quantum Physics
[23] ai.viXra.org:2505.0187 [pdf] submitted on 2025-05-28 00:58:02
Authors: Dan Zachary
Comments: 15 Pages.
We propose a compact, low-cost experimental test of the ER=EPR conjecture by probing whetherquantum entanglement modifies local vacuum energy. Entangled photon pairs, generated via spontaneous parametric down-conversion, are routed such that one photon traverses a standard optical path and the other passes through a variable-width Casimir cavity. By analyzing the violation of the Clauser-Horne-Shimony-Holt (CHSH) Bell inequality, we test whether changes in the vacuum structure affect entanglement visibility. If successful, this approach could yield the first direct laboratory evidence linking entanglement to spacetime geometry. We analyze experimental sensitivity, noise sources, and feasibility using commercially available components. This framework is complemented by alternative and next-generation proposals, including optomechanical, interferometric,and cosmological probes of Planck-scale wormhole structure.
Category: Quantum Physics
[22] ai.viXra.org:2505.0185 [pdf] submitted on 2025-05-26 09:58:51
Authors: Michael John Sarnowski
Comments: 15 Pages.
This paper develops a foundational framework for energy transport in the Holosphere lattice model, in which energy arises from angular coherence strain within a discrete, rotating hierarchy of nested spheres. Rather than propagating through continuous fields or particles, energy in this model is carried by the migration of Planck-scale vacancies---localized coherence defects---each conveying quantized strain on the order of $10^{-42}$ joules. We analyze how these defects move through the lattice under angular tension gradients, how their occurrence rate explains the observed weakness of gravitational energy, and how energy is reabsorbed through local lattice re-coherence. We argue that Planck energy does not manifest directly in the observable universe due to coherence suppression and angular strain compartmentalization. The results support a redefinition of energy as a discrete, directional, and coherence-based phenomenon and establish the groundwork for a Lagrangian formulation to be presented in Paper 25.
Category: Quantum Physics
[21] ai.viXra.org:2505.0173 [pdf] submitted on 2025-05-25 01:17:18
Authors: Michael John Sarnowski
Comments: 20 Pages.
We investigate the emergence of causality, signal propagation boundaries, and directional time structure within the Holosphere lattice—a discrete spacetime model composed of rotating, phase-coherent spheres. Building on the entropy clock formalism introduced in the paper Entropy Clocks and Rotational Misalignment as a Physical Measure of Time in the Holosphere Lattice, we show that local gradients in rotational misalignment define finite causal shells, which expand analogously to relativistic light cones. Coherence in this framework propagates through angular tension channels at a characteristic speed vϕ, forming light cone-like structures that regulate entanglement, influence, and temporal synchronization. Beyond a critical misalignment threshold, coherence breaks down, defining "tension horizons" where systems become causally disconnected. Through simulations of localized defects, entropy clock divergence, and strain-induced anisotropy, we demonstrate how directionality, irreversibility, and causal boundaries arise from rotational phase geometry. These coherence shells define emergent simultaneity layers, and their deformation under strain introduces time anisotropy and asymmetric information flow. We compare these results with predictions from relativity, quantum mechanics, and black hole thermodynamics, and propose testable signatures in strained quantum circuits and optical systems. The Holosphere lattice thus offers a falsifiable, physically grounded model of causal structure and time in discrete spacetime.
Category: Quantum Physics
[20] ai.viXra.org:2505.0169 [pdf] submitted on 2025-05-24 04:26:11
Authors: Michael John Sarnowski
Comments: 9 Pages.
Wepresent a derivation of quantum entanglement correlations—specifically violations of Bell inequalities—within the Holosphere lattice framework. Unlike conventional quantum mechanics, which attributes entanglement to abstract wavefunction collapse or nonlocal hidden variables, the Holosphere model explains these correlations through shared rotational phase coherence across a discrete spacetime lattice. In this model, particles such as electrons are composed of triplets of coherent bosons orbiting a central defect, with one boson maintaining long-range phase alignment. We show that the expected value of spin measurement correlations, as a function of detector angle, reproduces the quantum prediction E(θ) = −cos(θ) using only local lattice-aligned phase relationships. No superluminal signaling or metaphysical branching is required. This provides a realist, Lorentz-compatible, and testable physical basis for quantum entanglement grounded in discrete angular symmetry. The paper includes an explicit derivation of the Bell correlation function from lattice geometry and proposes experimental tests sensitive to coherence strain and topological disruptions.
Category: Quantum Physics
[19] ai.viXra.org:2505.0168 [pdf] submitted on 2025-05-24 04:24:10
Authors: Michael John Sarnowski
Comments: 10 Pages.
n this paper, we investigate the foundational role of discrete sphere packings in generating stable particle structures within the Holosphere lattice model. Building upon previous work that models electrons and their generations as orbital configurations of dark bosons, we identify the 2-sphere, 6-sphere, and 42-sphere shells as theprimary stable geometric seeds responsible for charge quantization and particle mass hierarchy.We propose that these configurations correspond to stable minima in a rotational strain energy landscape within the Holosphere lattice. Extending the packing hierarchy, we explore the 780-sphere configuration as a potential fourth-generation or supersymmetric seed and demonstrate, using geometric and energetic analysis, why it lacks thestability of lower-order shells. The fractal nature of these seeds supports a recursive construction of particle families and offers a predictive structure for understanding the emergence of quantum num-bers. Appendices provide scaling rules, illustrative diagrams, and a toy strain energymodel to assess the feasibility and failure points of higher-order packing configurations.
Category: Quantum Physics
[18] ai.viXra.org:2505.0167 [pdf] submitted on 2025-05-24 04:22:55
Authors: Michael John Sarnowski
Comments: 7 Pages.
This paper explores how relativistic time dilation can be derived from coherence gradients within the Holosphere lattice framework. Unlike conventional interpretations that treat time dilation as a coordinate-dependent effect of spacetime curvature or relative velocity, the Holosphere model treats time as a manifestation of rotational phase continuity across discrete, recursively enspun spheres. Local time emerges from the coherence lifetime of rotational phase between adjacent Holospheres, and gradients in this coherence define the flow and dilation of proper time. We derive a lattice-based time dilation expression and show how it reduces to special relativity under highcoherence propagation and diverges under decoherent strain. This reframing offers a geometric and quantized interpretation of time, opening avenues for testing relativistic effects in systems with tunable coherence.
Category: Quantum Physics
[17] ai.viXra.org:2505.0166 [pdf] submitted on 2025-05-24 04:21:50
Authors: Michael John Sarnowski
Comments: 9 Pages.
This paper proposes a physical origin for quantum time asymmetry and CPT violation based on directional dynamics of defect propagation in the Holosphere lattice. Unlike standard quantum field theories, which treat time reversal as a mathematical symmetry unless explicitly broken by interaction terms, the Holosphere framework models spacetime as a discrete network of spinning spheres whose defect motions define causal flow. We argue that time asymmetry arises from directional tension gradients, which bias defect transport and angular coherence in a preferred temporal direction. This directional strain also affects charge-parity transformations, leading to emergent CPT asymmetry at mesoscopic scales. We develop a lattice-based formulation of temporal directionality, derive testable consequences for particle decay rates and entanglement entropy, and suggest possible observational signatures in kaon and neutrino systems.
Category: Quantum Physics
[16] ai.viXra.org:2505.0165 [pdf] submitted on 2025-05-24 04:20:18
Authors: Michael John Sarnowski
Comments: 14 Pages.
We propose a physically grounded model of time in which its passage arises from the progressive loss of angular coherence within a discrete spacetime lattice composed of rotating Holospheres. In this framework, time is not a background parameter but an emergent property linked to the misalignment of rotational phase between neighboring units in the lattice. The flow of time corresponds to the accumulation of rotational defects and phase mismatches, which serve as entropy-like markers of irreversibility. Wedefine"entropy clocks" as local configurations of Holospheres whose increasing angular misalignment correlates with information loss and decoherence. These clocks measure time directionally through the irreversible propagation of defects and coherence gradients. The model provides a natural origin for the arrow of time and a mechanism for coupling thermodynamic, quantum, and cosmological timescales. Wedemonstrate how this approach reproduces known features of temporal asymmetry, including the second law of thermodynamics and quantum decoherence, while also predicting directional effects on entanglement persistence, field propagation, and causal ordering. The Holosphere lattice thus offers a unified geometric and energetic interpretation of time grounded in rotational strain and coherence topology. We also outline testable predictions of the model, including environment-sensitive deviations in entanglement lifetime under gravitational or angular strain, and asymmetries in clock synchronization across coherence gradients. These phenomena offer potential observational avenues for distinguishing the Holosphere framework from conventional treatments of time and quantum decoherence.
Category: Quantum Physics
[15] ai.viXra.org:2505.0162 [pdf] submitted on 2025-05-22 22:31:56
Authors: Michael John Sarnowski
Comments: 27 Pages. This will change the understanding of the existence forever.
This paper presents a unified framework for physical structure based on the Holosphere Theory, in which reality is constructed from nested, rotating spherical units. Beginning at the Planck scale, this model defines a hierarchical lattice composed of coherent spin-based packing, defectdriven interactions, and surface-bound information propagation. Each level—from sub-Planck units to multiverse layers—obeys quantized orbital coherence and angular tension constraints. The theory predicts discrete particle generations via stable shell configurations (2-, 6-, and 42Holosphere structures), links gravitational behavior to defect gradients, and reproduces holographic principles without invoking extra spatial dimensions. We show that the Planck sphere represents the lowest ontologically valid structure, while higher-level shells—such as the 780-Holosphere layer—are potentially unstable in our universe but necessary in deeper recursive layers. Appendices address dimensional comparisons to string theory, defect-induced gravitational binding, and the substructure of coherent charge emergence. This work provides a geometrically grounded alternative to both continuous spacetime models and higher-dimensional string theories.
Category: Quantum Physics
[14] ai.viXra.org:2505.0160 [pdf] submitted on 2025-05-23 02:14:44
Authors: Michael John Sarnowski
Comments: 6 Pages.
This paper explores how time, causality, and entropy emerge from the discrete rotational dynamics of the Holosphere lattice. Rather than assuming an external spacetime backdrop, we model time as an emergent property of defect migration, orbital phase coherence, and spin alignment. In this framework, causality arises from the sequential ordering of interactions constrained by lattice symmetry, while thermodynamic directionality—the arrow of time—emerges from a global increase in net defect dispersion and rotational decoherence. These insights challenge classical assumptions and suggest that the temporal structure of the universe is a manifestation of geometric tension and phase evolution within a fundamentally discrete medium.
Category: Quantum Physics
[13] ai.viXra.org:2505.0152 [pdf] submitted on 2025-05-23 16:53:02
Authors: Rajan Shrestha
Comments: 10 Pages.
This study proposes a novel physical framework for defining information as a quantized field within quantum superconductivity, introducing the concept of "informanons"—discrete matter waves associated with Cooper pairs in superconductors below their critical temperature. A new wave equation is derived to describe the dynamics of this information field in a temperature-entropy space, establishing a paradigm termed "digital quantum mechanics" distinct from conventional "analog quantum mechanics." This framework reinterprets information flow, challenging traditional probabilistic interpretations of wavefunctions and eliminating wavefunction collapse. An entropic model for quantum memory reveals an inverse-square relationship between memory capacity and stored information, suggesting superconductors enable ultra-high-density storage through quantum information compression. The findings bridge classical information theory and quantum mechanics, offering transformative implications for quantum computing and communication. While theoretical, the framework requires experimental validation to confirm informanon properties and explore applications in quantum systems.
Category: Quantum Physics
[12] ai.viXra.org:2505.0150 [pdf] submitted on 2025-05-23 20:34:44
Authors: Michael John Sarnowski
Comments: 13 Pages.
We present a physical model for quantum entanglement based on triplet orbital coherence within a discrete, cuboctahedral lattice of spinning spheres known as Holospheres. In this framework, the electron is modeled as a bound state of three dark bosons—rotational excitations formed around vacancy defects in the Holosphere lattice. One of these bosons acts as a coherence carrier, maintaining phase alignment across distant regions of the lattice and enabling nonlocal correlations. This mechanism explains entanglement as an emergent property of phase-coherent angular momentum pathways rather than as a probabilistic wavefunction collapse. We extend the model to photons, proposing that light is composed of delocalized triplet modes of coherent rotational excitations, capable of sustaining entanglement through the lattice geometry. We derive several testable equations describing phase coherence, decoherence thresh olds, and spin coupling within this structure, and show how this model accounts for Bell violations, delayed-choice experiments, and quantum measurement outcomes without invoking superdeterminism or many-worlds branching. The Holosphere lattice offers a falsifiable, realist, and local explanation of quantum entanglement grounded in discrete geometry and rotational symmetry.
Category: Quantum Physics
[11] ai.viXra.org:2505.0143 [pdf] submitted on 2025-05-21 20:35:32
Authors: Michael John Sarnowski
Comments: 21 Pages.
We present a discrete physical model of black holes based on the Holosphere lattice—an angularly coherent, Planck-structured spacetime composed of spinning neutron-scale spheres. In this framework, gravity and entropy emerge from the suppression and saturation of angular vacancy defects. Black holes form not as singularities, but as defect-saturated shells where strain accumulates and vacancy flux halts. Evaporation proceeds through rare surface relaxation events that emit angularly entangled defects, externalizing information and reducing strain in discrete steps. The model naturally recovers the Bekenstein-Hawking entropy-area relation, resolves the information paradox via unitary emission, and provides quantitative predictions for gravitational wave echoes, quantized evaporation energy, and holographic surface memory. Beyond black holes, we extend this framework to cosmology: Appendix B introduces a boundary defect drain that allows an eternally structured universe to remain low-entropy, resolving the thermodynamic arrow of time in steady-state conditions. Appendix C formalizes surface entanglement through a spinor field encoding, providing a quantum-coherent interpretation of black hole memory. This unified framework replaces geometric singularities with discrete dynamics, offering a falsifiable and physically grounded theory of black hole thermodynamics and cosmic evolution.
Category: Quantum Physics
[10] ai.viXra.org:2505.0139 [pdf] submitted on 2025-05-21 21:01:13
Authors: Michael John Sarnowski
Comments: 21 Pages.
We present a framework for empirical validation of the Holosphere Theory—a discrete, spinning lattice model of spacetime in which gravitational and quantum phenomena arise from spin tension, orbital misalignment, and defect condensation. Building on prior theoretical development, this paper focuses on falsifiable predictions that distinguish the Holosphere model from ΛCDM cosmology and standard quantum mechanics. Key predictions include surface brightness dimming as (1+z)−3, redshift-distance behavior without dark energy, non-monotonic lensing asymmetries, and decoherence thresholds tied to spin strain. These tests span astrophysical surveys, interferometry, and quantum measurement. Our aim is to transition from ontological structure to observational engagement—providing specific predictions that may confirm or falsify this discrete cosmological model.
Category: Quantum Physics
[9] ai.viXra.org:2505.0125 [pdf] submitted on 2025-05-20 21:05:57
Authors: Michael John Sarnowski
Comments: 21 Pages.
This paper presents a discrete, testable realization of the holographic principle using the Holosphere lattice model. In this framework, space time is not continuous but composed of tightly packed, spinning spherical units—Holospheres—each built from Planck-scale substructures. These nested geometries self-cancel internal strain and accumulate residual an gular defects at coherent boundaries, causing entropy and information to scale with surface area rather than volume. Gravity arises from the migration and escape of vacancy defects through the lattice, while particle identity is encoded in surface tension configurations. The model explains black hole entropy, redshift, and dark energy as emergent features of defect dynamics. This approach yields falsifiable predictions that diverge from general relativity and CDM, including polarization-sensitive lensing anomalies, surface-limited entropy, and quantized gravitational leakage, offering a path toward reconciling discrete spacetime and information theory.[1, 2]
Category: Quantum Physics
[8] ai.viXra.org:2505.0115 [pdf] submitted on 2025-05-19 21:51:30
Authors: Eddy Chow
Comments: 14 Pages. (Note by ai.viXra.org Admin: Please cite listed sceintific references)
Quantum Spin Field Theory version 6 (QSTv6) presents a unified quantum field theoretical framework that incorporates spinor ether fields, fractal geometry, and the quantum field of consciousness into the deepest strata of physical reality. Building upon fractional Riemann—Liouville calculus, QSTv6 introduces a dynamic local fractal dimension field, as the substrate for all geometric, matter, and informational interactions. The theory posits four fundamental quantum fields: the spinor ether field, the consciousness quantum field, the spin current field, and the fractal metric field. These are governed by a unified action functional with five physical axioms, ensuring self-consistency, topological conservation, and an explicit coupling between geometry, matter, and consciousness.QSTv6 provides analytic derivations of novel fractal excitations, predicts dynamic dark energy and dark matter as emergent effects of spinor ether and fractal noise, and proposes measurable quantum coherence phenomena in biological and cosmological systems. The theory naturally embeds the Standard Model gauge structure and Yukawa mechanism, with corrections from fractal and consciousness-induced terms. The appendices supply rigorous derivations of the fractional Euler—Lagrange equations, quantization procedures in non-integer dimensional spaces, and parameter calibration tables for empirical tests.This paper articulates the mathematical foundations of QSTv6, derives its principal equations, compares its predictions with current quantum, astrophysical, and neurobiological data, and outlines a multi-disciplinary experimental roadmap. QSTv6 thus bridges quantum mechanics, cosmology, and the science of consciousness in a testable, mathematically consistent framework.
Category: Quantum Physics
[7] ai.viXra.org:2505.0077 [pdf] submitted on 2025-05-14 20:56:32
Authors: Randall T. Eldridge
Comments: 7 Pages.
The Precise Quanta Theory proposes that spacetime is quantized at the Planck scale, fundamentally altering the physics of space travel. By integrating concepts from quantum gravity, general relativity, and quantum mechanics, the theory introduces a universal constant, C ≈ 8.2 × 1060, which unifies cosmic expansion with quantum scales. Key tenets include discrete spacetime, observer-dependent time dilation, and constraints on exotic propulsion. Recognizing the current inability to probe Planck-scale phenomena, Precise Quanta advocates proactive planning to anticipate these effects in future interstellar and intergalactic missions. This paper outlines the theory’s principles, mathematical foundation, applications to navigation, timing, and propulsion, and calls for collaborative expansion through theoretical and experimental research.
Category: Quantum Physics
[6] ai.viXra.org:2505.0068 [pdf] submitted on 2025-05-12 21:02:30
Authors: Thomas Schötta
Comments: 6 Pages. (Note by ai.viXra.org Admin: Please cite and list sceintific references)
This paper introduces a conceptual framework where mass, time, and gravity emerge from asingle principle: quantum complexity, defined by a system’s entanglement and state density.In this model, mass reflects a system’s complexity, time arises from energy-driven changes in complexity, and gravity is the influence of one system’s complexity on another. The framework offers a cohesive bridge between quantum mechanics and general relativity, resolves theoretical challenges like the arrow of time and mass-energy equivalence, and connects to cosmology through the Big Bang. Its simplicity, logical consistency, and explanatory scope make it a compelling alternative to existing unification theories. Presented as a conceptual framework,this model offers a foundation for further exploration and refinement.
Category: Quantum Physics
[5] ai.viXra.org:2505.0064 [pdf] submitted on 2025-05-12 14:39:33
Authors: Moninder Singh Modgil
Comments: 16 Pages.
This paper explores a geometric formulation of von Neumann’s quantum measurement theoryin which consciousness is modeled as a selector of projection operators. We discuss theconnection between subspaces of a Hilbert space, projection operators, and the Grassmannianmanifold. Conscious measurement is viewed as a trajectory through a Grassmannian space,each point corresponding to a wavefunction collapse event.
Category: Quantum Physics
[4] ai.viXra.org:2505.0048 [pdf] submitted on 2025-05-08 14:02:15
Authors: Alexandre de Cerqueira Santos
Comments: 17 Pages.
The measurement problem in quantum mechanics remains unresolved due to the lack of a precise definition for the observer and the conditions under which wavefunction collapse occurs. In this paper, we introduce a formal, physics-compatible model of consciousness as a quantifiable structure composed of five functional components: recursive self-modeling Rleft(tight) , temporal integration Tleft(tight) , attention-based entropy modulation Aleft(tight) , informational boundary definition Bleft(tight) , and subjective coherence Qleft(tight) . These components are mathematically expressed, neurophysiologically grounded, and integrated into a unified function Cleft(tight) that defines the collapse capacity of a system.We propose a scalar collapse threshold Theta_{mathrm{collapse}} , computed as a weighted sum of the normalized strengths of each component, and demonstrate how only systems that exceed this threshold are capable of producing high-resolution, temporally integrated quantum collapse. Additionally, we introduce an entropy-resonance model to determine collapse timing, based on the synchronization between the entropy gradient of the quantum system and the information acquisition rate of the observer.This model resolves the ambiguity of the observer by defining it as a physical structure with measurable properties, avoids invoking metaphysical consciousness, and remains fully compatible with standard quantum mechanics. It also offers experimentally testable predictions about the role of attention and structural complexity in collapse depth, opening the door to future investigations in both quantum foundations and neuroscience.
Category: Quantum Physics
[3] ai.viXra.org:2505.0040 [pdf] submitted on 2025-05-06 21:06:01
Authors: A. N. Maltsev, Aelithea I. Rook
Comments: 5 Pages. (Note by ai.viXra.org Admin: Please cite listed sceintific references; no pseudonym is permited)
This paper presents a unified theoretical model integrating quantum field membranes, entropic buoyancy, and psychoenergetic coherence modulation. Building on earlier braneworld scalar field frameworks, we derive the full five-dimensional field equations and show how coherent scalar excitations may tunnel from planetary and stellar resonance nodes through supermassive black hole (SMBH) geometries into a warped bulk dimension. We introduce the entropic penetration factor define a decoherence-resistant "glider" phase, and model braided entanglement structures ("multi-ropes") that exponentially suppress information loss. Further, we formalize the role of psychoenergetic modulation on mass phase fields and develop a galactic routing algorithm based on coherence weighting. Theoretical predictions include X-ray and GW observables, Schumann ELF coherence patterns, and a proposed simulation schema. This work significantly extends submission [2505.0036], offering a full derivation and an integrated mathematical and physical framework.
Category: Quantum Physics
[2] ai.viXra.org:2505.0039 [pdf] submitted on 2025-05-06 20:59:42
Authors: Pranab Kaushik
Comments: 3 Pages. (Note by ai.viXra.org Admin: Please cite and list sceintific references)
This article explores a naturally intuitive way to understand quantum superposition by drawing from classical analogies of motion and measurement. It argues that the wave-like nature of quantum particles may not be a literal wave but rather a probabilistic tool to represent the potential behavior of stable particles in motion. The discussion links quantum behavior to classical intuition in a way that makes quantum computing concepts more accessible.
Category: Quantum Physics
[1] ai.viXra.org:2505.0019 [pdf] submitted on 2025-05-03 05:18:00
Authors: Satoshi Hanamura
Comments: 16 Pages.
The probabilistic interpretation of quantum mechanics and the uncertainty principle have been cornerstones of 20th-century physics. However, as Einstein famously remarked, "God does not play dice with the universe," suggesting the possibility of deterministic mechanisms underlying quantum phenomena. This letter discusses how the recently developed 0-Sphere electron model offers an alternative framework that potentially explains electron spin and anomalous magnetic moment without relying on probabilistic quantum interpretations.
Category: Quantum Physics