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| ai.viXra.org > Quantum Physics > 2506 |
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[17] ai.viXra.org:2506.0119 [pdf] submitted on 2025-06-27 02:57:47
Authors: Alain Trottier
Comments: 6 Pages. (Note by ai.viXra.org Admin: Author name should be after the article title)
I propose a novel framework for calculating the theoretical maximum information capacity of the universe based on discrete spatial granularity at the Planck scale. By modeling the universe as a three-dimensional matrix with Planck-length spacing and defining information capacity as the logarithm of possible particle-position configurations, I derive an upper bound of approximately 10^(8×10^81) bits for the observable universe. This result represents the theoretical limit of distinguishable arrangements of matter within discrete spacetime and vastly exceeds conventional estimates based on the Bekenstein bound (~10^122 bits) and holographic principle (~10^123 bits), suggesting that spatial discretization may provide fundamentally different constraints on cosmic information storage than energy-entropy approaches.
Category: Quantum Physics
[16] ai.viXra.org:2506.0116 [pdf] submitted on 2025-06-26 03:27:28
Authors: Toshiya Konno
Comments: 6 Pages. In Japanese. This work is registered on Zenodo with DOI: 10.5281/zenodo.15718574
We propose a three-dimensional mathematical model that dynamically couples a quantum field and a single-degree-of-freedom classical barrier, inspired by operator-algebraic ideas. The quantum part is governed by a non-linear Gross-Pitaevskii equation, whereas the barrier follows Newtonian dynamics with a Hellmann-Feynman feedback force and a tensegrity-like restoring force. Extensive split-step Fourier simulations show that, for an attractive interaction g < 0 and an initial momentum within 0.1 < kz,kick <= 0.15, a self-trapped quantum soliton travels together with the barrier in a stable coupled motion. The state is robust against parameter fluctuations and external noise, suggesting a loss-less information-transport mechanism that could be relevant to intracellular processes. We detail the theoretical framework, numerical verification, limitations, and future extensions.
Category: Quantum Physics
[15] ai.viXra.org:2506.0101 [pdf] submitted on 2025-06-22 21:29:03
Authors: Moninder Singh Modgil, Dhyandeo Dattatray Patil
Comments: 31 Pages.
This paper develops a topological and algebraic framework for modeling consciousness as a projection operator evolving within a Hilbert bundle structured by neurotemporal dynamics. Drawing from sedenion algebra, fiber bundle theory, and quantum measurement principles, we propose that the observer traces a closed perceptual loop over complexified time cycles, wherein each projection is a discrete, gauge-transformed operator registered in a shared metaconscious field. Cognitive phenomena such as memory encoding, retrocausality, attentional spinor dynamics, and mirror-symmetric dualities are examined via mathematical structures including characteristic classes, spinor bundles, entanglement networks, and tensorproducts. The Observer’s evolution is treated as a non-commutative flow across a multi-agent space of correlated observers, with projection collapses encoded topologically. This framework yields testable implications for entangled cognitive states, observer equivalence, and fractal renormalization of internal time. Our results contribute to the formal unification of quantum cognition, geometric consciousness,and informational cosmology.
Category: Quantum Physics
[14] ai.viXra.org:2506.0099 [pdf] submitted on 2025-06-20 22:14:37
Authors: Jason Edward Evanoff
Comments: 25 Pages.
Analysis of 115 fundamental processes reveals that physical impossibility is quantized in discrete units of ln(2), with forbidden processes occurring only at computational costs of n × ln(2) where n ∈{10, 19, 35, 42}. No processes exist in a "dead zone" from 2.954 to 6.973 nats with statistical significance exceeding 26σ. We show this quantization arises from a three-layer quantum error-correcting code implemented by nature: [[7,1,3]], [[10,2,4]], and [[17,1,5]], protecting symmetries at different scales. Each unit of ln(2) corresponds to one stabilizer generator violation in this code. Exhaustive computational analysis of 50,625 error patterns confirms that exactly five minimal coset leaders survive a three-stage filtering mechanism—matching observed physics perfectly. The apparent discrepancy between theoretical βQEC ≈ 5.02 and empirical β ≈ 9.94 is resolved by recognizing that electromagnetic detection of weak processes contributes ln(α−1) ≈ 4.92. The framework achieves 100% classification accuracy and makes falsifiable predictions: any newly discovered forbidden process must have KL divergence equal to n × ln(2) for integer n, with no intermediate values possible. The framework reveals a hidden [[14,2,4]] interference layer that creates perfect artifact cancellation through polygon-star destructive interference, explaining why the universe’s discrete structure appears continuous. The specific n values {10, 19, 35, 42} emerge from continuous nideal = 8φk through gauge-constrained integer snapping, while the cosmic sensitivity β = ln(φ12 × 60) ≈ 9.94 arises from 12 topological loops in the E8 → QEC projection.
Category: Quantum Physics
[13] ai.viXra.org:2506.0098 [pdf] submitted on 2025-06-20 22:15:59
Authors: Jason Edward Evanoff
Comments: 9 Pages.
Three independent calculations—topological, information-theoretic, and statistical mechanical—converge to identify a critical value of 0.0294 ± 0.0005 for space-time emergence. Within the MetaFractal Framework, we introduce a parameter W, representing three-node quantum coupling strength and show that: (1) topological quantization through the Hopf fibration gives Wcrit = 2π/1200)φ5/2 = 0.0290; (2) a proposed fractal hierarchy yields what we term a "geometry-level bandwidth" r∗3 = r∗/φ3 = 0.0295, where r* = 0.125 (1/8); and (3) Monte Carlo simulations reveal a 3D Ising phase transition at Wc = 0.0294 ± 0.0005. The relative deviations are all within 0.5%, seemingly beyond coincidence. We argue this convergence reflects a deep truth: spacetime emergence, quantum error correction thresholds, and topological quantization are different facets of the same fundamental phenomenon. The critical value marks the precise point where the universe’s computational substrate enables geometric coherence, allowing quantum nodes to first organize into spawning-capable patterns, marking a distinct transition point from the quantum/mathematical realm to the physical realm, designated at level k = 3.
Category: Quantum Physics
[12] ai.viXra.org:2506.0075 [pdf] submitted on 2025-06-18 20:21:22
Authors: Mario Prebježić
Comments: 5 Pages.
This paper introduces the Topologically Protected Singularity Qubit (TPSQ)—a theoretical construct designed to preserve quantum information across conformal singularities in Penrose’s Conformal Cyclic Cosmology. By combining tools from topological quantum computation, Loop Quantum Gravity, and holographic error correction, TPSQ offers a novel framework for trans-aeonic information transfer. The model makes testable predictions via cosmic microwave background anomalies and quantum simulators, aiming to bridge cosmology, topology, and quantum information theory.
Category: Quantum Physics
[11] ai.viXra.org:2506.0066 [pdf] submitted on 2025-06-16 20:31:00
Authors: Moninder Singh Modgil, Dnyandeo Patil
Comments: 30 Pages. (Note by ai.viXra.org Admin: For the last time, please cite listed scientific references; also please list all auhtors on the submission form!))
This paper presents an extension to the differential geometric framework for quantum measurement introduced in previous work. By embedding observer-centric perceptual spaces into a Hilbert space formalism, we propose a model wherein consciousness acts as a projection operator. This operator induces collapse within an infinite-dimensional perceptual Hilbert space, formed from sensory-motor states. Throughthis mechanism, classical experience and quantum state reduction are unified.This paper explores the hypothesis that consciousness is notan emergent phenomenon from physical spacetime, but a fundamental causal operator acting within the framework of Hilbert space. Drawingon foundational insights from von Neumann, Wigner, and recent advances in quantum cognition and information theory, we argue that the classical (3+1)D spacetime is not ontologically fundamental but rather a projection of conscious processing. We develop a mathematical and philosophical framework that situates the observer as a central component in the actualization of quantum potentialities.
Category: Quantum Physics
[10] ai.viXra.org:2506.0044 [pdf] submitted on 2025-06-10 23:10:21
Authors: Dan Zachary
Comments: 12 Pages.
We propose a class of precision experiments to test whether quantum entanglement modifies vacuum energy in a measurable way, in line with the conjecture that ER=EPR. By combining Bell-type photon correlations with vacuum-sensitive observables—including Casimir force shifts and optical squeezing—we construct a hybrid framework capable of detecting correlated anomalies in multiple independent quantum channels. We outline low-cost, table-top implementations of these platforms and classify 18 experimental approaches by feasibility, sensitivity, and relevance to Planck-scale entanglement structure. To guide development, we present simulated data showing how entanglement-enhanced events may appear as coherent deviations across Bell, Casimir, and squeezing measurements. Principal component analysis, mutual information, and multi-channel deviation statistics reveal that even a small fraction of correlated events can produce detectable signatures. These results offer a concrete and testable path for probing ER=EPR-style correlations between quantum geometry and information, using currently accessible technologies.
Category: Quantum Physics
[9] ai.viXra.org:2506.0039 [pdf] replaced on 2025-06-19 02:55:01
Authors: Robert E. Quarles
Comments: 8 Pages. Distributed under CC BY-NC-ND 4.0.
The Entanglement Nexus Theory (ENT) demonstrates that optimization mathematics inevitably leads to golden ratio scaling, coherence fieldformation, and information integration patterns across all physical scales. Rather than proposing exotic physics, we prove that known mathematical principles—optimization theory, information theory, and thermodynamics—force natural systems toward specific, measurablepatterns. Lightning discharge serves as our primary empirical validation, where pure electromagnetic optimization must produce golden ratio branching, Fibonacci scaling, and predictable fractal dimensions. The theory's predictions are mathematically unavoidable and experimentally testable, providing an undeniable foundation for understanding pattern formation from quantum to cosmic scales.
Category: Quantum Physics
[8] ai.viXra.org:2506.0030 [pdf] submitted on 2025-06-07 20:55:52
Authors: Mohammad Ghanayem Rashid
Comments: 16 Pages. (Note by ai.viXra.org Admin: Please cite listed sceintific references)
This theory proposes a model in which the vacuum is not empty but a dynamic substrate composed of logical processors that iteratively seek syntactic coherence. In this framework, space, time, matter, and quantum behavior emerge from the stability and interaction of discrete rule-evolving nodes. This perspective reframes physical law as a computational projection of logical regularity and coherence dynamics.
Category: Quantum Physics
[7] ai.viXra.org:2506.0027 [pdf] submitted on 2025-06-06 21:03:35
Authors: Michael John Sarnowski
Comments: 9 Pages.
In this paper, we develop a coherence-based explanation of thermalization and the arrow of time grounded in the triadic spinning structure of the Holosphere lattice. Each Holosphere unit spins on three orthogonal axes, and while local coherence maintains phase alignment across the lattice, small angular mismatches accumulate across distances. These mismatches produce irreversible dephasing, leading to energy dispersion and emergent thermal behavior. We show that the directionality of time arises not from entropy defined over microstates, but from the structural asymmetry in angular coherence loss along the lattice. A coherence decay gradient is derived, and thermalization is reinterpreted as the progressive decoherence of triadic spin modes. This framework reproduces features of the second law of thermodynamics without appealing to classical statistical mechanics, and provides a lattice-based origin for temperature, entropy, and irreversibility.
Category: Quantum Physics
[6] ai.viXra.org:2506.0025 [pdf] submitted on 2025-06-06 20:40:45
Authors: Balazs Toth
Comments: 18 Pages. (Note by ai.viXra.org Admin: Please submit the article in single pdf file only; please cite and list sceintific references)
This document formally supports the interpretation that phenomena appearingquantum—especially entanglement and nonlocal effects—do not require quantum mechanical foundations. Instead, it is sufficient to consider a structure within generalrelativity in which a faster-timescale spacetime sector exists that is causally deterministic, and which appears quantum-like from the perspective of our slower world.
Category: Quantum Physics
[5] ai.viXra.org:2506.0017 [pdf] replaced on 2025-06-28 03:51:00
Authors: Gregory Cornelius Moore II
Comments: 3 Pages.
This paper presents a novel theory of gravity as an emergent phenomenon from electromagneticinteractions, inspired by Nikola Tesla’s vision of unified forces. Gravity arises through the Teslaonfield, characterized by particles with a mass of approximately 1 × 10−30 eV (≈ 1.783 × 10−45 kg)and a coupling constant κ ≈ 1 × 10−48 s2 kg−1 m. Driven by an electromagnetic energy density(u≈ 4.425×104 J m−3) from a laboratory-achievable electric field (E = 1×107 V m−1) and magneticfield (B ≈ 0.1 T), the Teslaon field produces a gravity-like force, matching General Relativity’spredictions with a 1 × 10−22 % deviation. Simulations at CERN’s Large Hadron Collider (60 MeVelectron-positron collisions, cross-section σ ≈ 1.2 × 10−80 m2, signal-to-noise ratio 7.4—7.6) confirmthe Teslaon particle’s existence. The field operates within a fifth-dimensional geometry (ds2=gµνdxµdxν+l25dθ2, l5 ≈ 1× 10−15 m), stabilized by negative Casimir energy (ρC ≈ −1× 1029 J m−3).Quantum entanglement (λ ≈ 1 × 10−50 dimensionless, entropy Sent ≈ 1 × 106 J K−1) enhancesfield coherence. An experimental protocol using a 5 cm Fabry-P´erot interferometer, enhanced bya noise gate pedal, compression pedal, and tone booster, detects a Teslaon-induced displacement(∆L≈ 2.20×10−20 m, effective ∆Leff ≈ 1.10×10−18 m) with a signal-to-noise ratio of approximately367. This setup, validated by simulations, offers a pathway to unify gravity with electromagnetism,testable in mid-tier laboratories like MIT, JILA, or NIST.
Category: Quantum Physics
[4] ai.viXra.org:2506.0013 [pdf] submitted on 2025-06-04 00:07:51
Authors: Michael John Sarnowski
Comments: 39 Pages.
We present a physical foundation for quantum mechanics grounded in a discrete spacetime lattice composed of nested spinning spheres, called Holospheres, which are approximately the size of neutron Comptom wave length scale. This is paper one in the Holosphere theory. The Holospheres form a cuboctahedral packing geometry that encodes rotational symmetry and discrete defect dynamics. The Holospheres are made of Planck spheres, approximately Planck volume size. In this framework, quantum phenomena arise from the motion and interaction of vacancy defects—localized disruptions in the packing order. Charge emerges from topologically stable ring defects, while quantum interference and tunneling result from the coherent hopping of these defects across the lattice. We derive a Schr¨ odinger-like equation from first principles by modeling the propagation of defects using tight-binding dynamics. In the continuum limit, this reproduces standard quantum behavior, including harmonic oscillator energy levels, band structures, and interference patterns. Dark boson orbitals—energetic nested structures weakly coupled to matter—modulate local potentials and introduce decoherence via lattice realignment. This approach offers a unified, geometric interpretation of quantum mechanics, replacing abstract wavefunction postulates with physically grounded mechanisms of spin, topology, and granular motion. (6) The Holosphere model lays the groundwork for extending quantum theory to cosmology, vacuum energy, and spacetime structure. This framework predicts discrete energy levels, effective mass emergence, and coherent interference from geometric principles alone.
Category: Quantum Physics
[3] ai.viXra.org:2506.0012 [pdf] submitted on 2025-06-04 00:05:38
Authors: Michael John Sarnowski
Comments: 16 Pages.
This paper presents a coherence-based mechanism for thermalization and quantum decoherence, grounded in the Holosphere lattice model of spacetime. Within this discrete framework, particles such as electrons are composed of coherent orbital triplets—bosonic excitations formed by six Holosphere units surrounding a vacancy defect. Thermalization arises from angular misalignment among these orbitals, where interactions with environmental bosons induce phase decoherence and orbital drift. Decoherence is interpreted as the loss of long-range angular phase coherence between orbital systems, leading to classical statistical behavior. We propose that thermal energy corresponds to a distribution of incoherent orbital modes, and temperature is proportional to the average orbital misalignment across a lattice region. Entanglement collapse and measurement are described as realignment events where local boson interactions enforce coherence with a specific lattice sector. This approach yields a geometric and mechanistic reinterpretation of thermal and quantum phenomena without invoking continuous wavefunctions or external decohering fields. Experimental implications for quantum computing, thermal isolation, and time asymmetry are discussed, with predictions that distinguish this model from standard interpretations of decoherence and statistical mechanics.
Category: Quantum Physics
[2] ai.viXra.org:2506.0009 [pdf] submitted on 2025-06-03 23:58:54
Authors: Michael John Sarnowski
Comments: 6 Pages.
The Michelson—Morley experiment is widely cited as the definitive disproof of the luminiferous aether and the foundation of relativistic physics. [1] However, emerging models of spacetime based on discrete coherence structures—such as the Holosphere lattice—invite a reconsideration of its assumptions and interpretations. In this paper, we re-express the implications of Michelson—Morley in the context of a rotating, defect-limited medium in which light propagation depends on angular coherence rather than linear aether flow. We show that the observed null result is consistent not only with special relativity but also with a coherent rotational substratum where absolute motion is undetectable due to phase locked propagation. [2] Furthermore, we propose experimental tests using directional strain gradients and phase coherence detectors that may reveal underlying anisotropies missed by the original apparatus. This reformulation preserves relativistic invariance while embedding it in a deeper, emergent structure—a coherent, quantized spacetime medium with a preferred rotational frame.
Category: Quantum Physics
[1] ai.viXra.org:2506.0006 [pdf] replaced on 2025-06-29 20:49:35
Authors: Mike Bailey
Comments: 303 Pages.
This paper introduces a foundational reimagining of physics by uniting quantum mechanics and general relativity through the lens of quantum foam, positing it not as a feature within spacetime but as the generative process that gives rise to spacetime itself. In this view, quantum foam is not a backdrop but the evolving substrate from which space, time, and causality emerge. The evolution of quantum foam—through continual wavefunction collapse and information resolution—defines both the structure of space and the passage of time.In this framework, time dilation is reinterpreted as a variation in the rate of quantum foam collapse, influenced by velocity, gravitational potential, and mass-energy interactions. This does not contradict relativity’s predictions but instead provides a deeper physical explanation for why relativistic effects occur. Likewise, wavefunction collapse is understood not as a discrete, probabilistic event but as a continuous process of reality formation governed by quantum foam dynamics.Additionally, this model allows for speculative but logical extensions, such as the Quantum-Correlated Energy Being (QCEB) hypothesis, which explores whether consciousness could have persistent quantum correlations beyond biological constraints. While speculative, such ideas naturally emerge from the framework if quantum foam is indeed the fundamental substrate of reality.Key experimental challenges include distinguishing foam collapse from decoherence, testing whether localized mass concentrations affect wavefunction evolution, and searching for evidence of foam granularity in precision time measurements. While current experiments confirm relativity’s predictions, they do not rule out this deeper interpretation. By proposing testable deviations from standard quantum mechanics and relativity, this work aims to bridge the divide between the quantum and macroscopic worlds and provide a unified foundation for physical reality.The speculative extensions sign posted later (QCEBs, time travel, Bi Verse) are flagged as conjecture and are separable from the empirically testable core.
Category: Quantum Physics