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| ai.viXra.org > Quantum Physics > 2503 |
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[4] ai.viXra.org:2503.0022 [pdf] submitted on 2025-03-31 12:52:04
Authors: A. Schubert
Comments: 10 Pages.
We propose a novel framework in which quantum measurement is interpreted as a dualentropic projection at a thermodynamic interface—specifically, a dynamically active eventhorizon (EH) that connects an AdS-like quantum domain with a dS-like geometric spacetime.Building on earlier work on dual-holographic cosmology and thermodynamic gravity, wesuggest that the EH field Φ serves as an informational screen, where both position and spinare projected independently from a common superposed quantum state.At the core of this model lies the entropic structure of the EH potential, which naturallyexhibits a Gaussian profile. This structure encodes a global equilibrium condition dS = 0that characterizes both the interior (AdS) and exterior (dS) domains. We interpret quan-tum measurement as a thermodynamic sampling from this global standard distribution: aprojection occurs when a local fluctuation creates a momentary "gap"—an entropic devia-tion—that allows one component of the superposition to "fall" into a classically observablestate.This process respects conservation laws of energy, momentum, and helicity, but breakslocal determinism, aligning with Bell’s theorem through a nonlocal variable encoded inthe EH geometry. The duality of projection—spin from AdS, position from dS—leads tocorrelated outcomes without signal exchange, suggesting a fundamentally entangled butthermodynamically governed universe. The statistical symmetry that underlies quantummechanics may thus reflect the thermodynamic drive toward global equilibrium in a dualholographic setting.
Category: Quantum Physics
[3] ai.viXra.org:2503.0021 [pdf] submitted on 2025-03-31 14:58:20
Authors: Peter Dolansky-Gentner
Comments: 3 Pages.
We introduce the Quantum Equilibrium Principle (QEP), a novel framework that describes wave function collapse as an entropy-driven equilibrium-seeking process. QEP refines the conventional collapse model by incorporating entanglement strength and environmental decoherence as key factors influencing the collapse rate. The resulting formulation presents a quantifiable collapse rate equation, distinct from Many-Worlds and gravity-based interpretations, and testable via quantum computing, Bell’s theorem experiments, and quantum thermodynamics. Our approach suggests that quantum systems inherently tend toward equilibrium, governed by an entropy decay function rather than an instantaneous measurement-induced collapse.
Category: Quantum Physics
[2] ai.viXra.org:2503.0017 [pdf] submitted on 2025-03-30 01:04:00
Authors: Justin Erimodafe
Comments: 3 Pages.
This paper presents an alternative interpretation of electron behavior in quantum mechanics, proposing that electrons switch between particle and wave states upon measurement, rather than existing in a superposition of both states. The theory offers a non-superposition-based view of quantum phenomena, addressing the standard wave-particle duality through a simplified model in which the electron behaves as a wave when unmeasured and behaves as a particle upon interaction with a measuring device. This interpretation challenges traditional views of quantum superposition and collapse, providing a more intuitive understanding of electron behavior in specific experimental contexts.
Category: Quantum Physics
[1] ai.viXra.org:2503.0007 [pdf] submitted on 2025-03-29 00:22:27
Authors: Ryan Wallace
Comments: 11 Pages.
Decoherence is a fundamental challenge in quantum mechanics, resulting in phase coherence loss and a transition from quantum to classical behavior. The Structured Energy Return (SER) model proposes afeedback-based mechanism that actively reshapes coherence loss. Here,we extend our previous findings by systematically exploring the parameter space involving coupling and feedback strengths. The results highlightrobust scale-invariance and clarify optimal operating conditions, significantly enhancing the practical applicability of the SER model. The SERModel shows that it can:u0088 Can redistribute coherence loss over time instead of merely slowingit,u0088 Sometimes re-purifies the system to a near-pure state (especially in2×2 simulations),u0088 In higher dimensions (e.g., 4×4), can drive the system toward apartially mixed but stable state—maintaining significant coherence,u0088 In physically realistic quantum-optical systems (e.g., Jaynes—Cummings model), sustains Rabi oscillations and partially preserves qubitcoherence.This unified document outlines the development of SER, from the earliestsingle-particle wavefunction formulation to the Lindblad-based densitymatrix approach, culminating in positivity-enforced simulations acrossmultiple system sizes and the latest Jaynes—Cummings results.
Category: Quantum Physics