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| Main Authors: | , |
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| Format: | Recurso digital |
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Zenodo
2026
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| Online Access: | https://doi.org/10.5281/zenodo.19687869 |
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Table of Contents:
- <p class="p">The fundamental properties and behavioral patterns of neutrinos constitute profound puzzles that go beyond the Standard Model of particle physics. Mainstream theories, relying on quantum field theory and the relativistic mass-energy equivalence, have introduced numerous free parameters and conceptual complexities in explaining phenomena such as the origin of neutrino mass, flavor oscillations, and the solar and reactor neutrino flux anomalies. This study aims to provide a unified and self-consistent explanatory framework for the nature of neutrinos and related physical phenomena based on the classical realist "Great Tao Model." Starting from the principle of Yin-Yang and physical facts, the model establishes electrons, positrons, and Substons as the only elementary particles, and rigorously derives that the neutrino is by no means an elementary particle but a stable composite system formed by the combination of an electron and a positron (ν ≡ <em>e</em><sup><span>-</span></sup><em>e</em><sup><span>+</span></sup>). Based on this ontological reconstruction, the study systematically explains that the neutrino mass is approximately twice the electron mass, that "flavor oscillations" are in fact a continuous classical evolution of the composite system among different internal dynamical states, that solar neutrinos originate primarily from the "Radiation-Combination Reaction (RC reaction)" inside stars rather than the proton-proton chain, and that other experimental anomalies can be attributed to an incomplete understanding of the interaction cross-sections of composite particles. This framework not only provides coherent answers to long-standing puzzles but also proposes unique, experimentally testable predictions that stand in sharp contrast to mainstream theories, offering a new paradigm and test targets for neutrino physics.</p>