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Causal Revelation and Structured Superposition in the Quantum Field: A Reformulation Based on QOFF

Name: Causal Revelation and Structured Superposition in the Quantum Field: A Reformulation Based on QOFF
Creator: pozzi, michaël
Keywords: Measurement, Causal interpretation, Phase coherence, Vibratory modes, Lagrangian formulation, Schrödinger equation, Wave-based quantum theory, Structured vacuum, Resonance, Non-collapse measurement

descriptionPublicationkeyboard_double_arrow_right Preprint 14 May 2025Publisher:Zenodo

Authors: pozzi, michaël;

doi: 10.5281/zenodo.15399927 , 10.5281/zenodo.15626935 , 10.5281/zenodo.15399862

Causal Revelation and Structured Superposition in the Quantum Field: A Reformulation Based on QOFF

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Abstract

This work is part of the ongoing development of the Quantum Ondulatory Force Field (QOFF) theory, which proposes a deterministic and physically grounded framework for understanding quantum phenomena. The central claim of this article is that quantum superposition is not an abstract probability amplitude, but a real and structured vibratory configuration in the quantum field. Measurement is modeled as a resonant filtering process, not a probabilistic collapse. The article introduces a Lagrangian extension to describe the field dynamics and proposes a causal reinterpretation of the Schrödinger equation, consistent with observed outcomes but based on vibratory coherence. The analogy of a prism decomposing light is used to illustrate how detection reveals rather than creates quantum outcomes. Theoretical consequences, falsifiability conditions, and implications for future experimental tests are discussed.

Keywords

Measurement, Causal interpretation, Phase coherence, Vibratory modes, Lagrangian formulation, Schrödinger equation, Wave-based quantum theory, Structured vacuum, Resonance, Non-collapse measurement, Deterministic physics, Wavefunction, Manifestation function, Quantum field, Quantum ontology, Quantum superposition

1 Research products, page 1 of 1

Title – Causal Revelation and Structured Superposition in the Quantum Field: A Reformulation Based on QOFF Abstract This article proposes a deterministic reinterpretation of quantum superposition through the lens of the Quantum Ondulatory Force Field (QOFF). Instead of viewing a system as a probabilistic sum of potential states, we treat the quantum field as a structured ensemble of real vibratory modes. Observable phenomena emerge not by collapse, but through phase-coherent resonance with external perturbations. Using the analogy of a prism decomposing white light, we demonstrate how measurement acts as a selective filter that reveals pre-existing wave components. A Lagrangian formulation and a causal reinterpretation of Schrödinger's equation are introduced to ground this model in rigorous field dynamics. The resulting framework replaces the probabilistic Born rule with a manifestation function based on vibratory overlap, opening the way to falsifiable predictions and a physically grounded understanding of quantum behavior. ________________________________________ Chapter 1 – Structured Superposition and the Prism Analogy 1.1 – From Probabilistic Collapse to Resonant Revelation ________________________________________ 2.2 – The Prism Analogy: Resonance as Selective Revelation Just as a prism does not generate colors but spatially separates the existing frequencies within white light, a measuring device does not create a particle. It reveals the component of the wavefield that matches its frequency, phase, and spatial coherence. In QOFF, this analogy becomes mathematically meaningful: observation acts like a resonance filter applied to the field, enhancing the mode that aligns best with the ________________________________________ 2.3 – Lagrangian Extension and Schrödinger Reinterpretation b) Causal Schrödinger Reformulation: ________________________________________ 2.4 – Predictions and Experimental Falsifiability Note: While the proposed equations are internally consistent and provide a causal alternative to the probabilistic framework, QOFF requires further refinement to fully model quantized field interactions (e.g., spin, entanglement, full electromagnetic structure). Its validity must be tested in experimental configurations where standard quantum predictions diverge from resonance-based outcomes. ________________________________________ 2.5 – Implications and Outlook • Quantum states are not abstract vectors but real waves in structured superposition. • Measurement is a filtering interaction, not a projection. • Predictions become phase-dependent and falsifiable. This formulation aligns with all standard results while providing a deterministic, physical foundation for quantum emergence.
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