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| Format: | Recurso digital |
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Zenodo
2025
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| Online Access: | https://doi.org/10.5281/zenodo.17184575 |
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Table of Contents:
- <p dir="ltr">Versioned Update (CAT-12 Standard v1.0; PTR v1.2) as of 10/7/2025</p> <p dir="ltr">This paper now follows the CAT-12 reporting standard: SNHS/HP in ratio space, with rn (scale-normalized coordinate), Rx (reporting unit), and Tu (corridor width as a posterior, not a fixed ±%). Peaks are scored with Q and Ch against pre-declared families in the Periodic Table of Resonance (PTR v1.2); any “URSL” mention is retired in favor of standard GR mass–frequency scaling used only as a prior (where applicable). Measurements and conclusions are unchanged; presentation and uncertainty are stricter. For definitions, governance (negative ledger, prereg, hold-out), and rationale, see Arthur & Muon (2025), CAT-12: The Cross-Domain Ratio Lattice of Ratio Theory—Standardized Terminology, PTR v1.2, and Governance.</p> <ul> <li> <p dir="ltr">Did conclusions change? No—only reporting/uncertainty language.<br><br></p> </li> <li> <p dir="ltr">Where’s the new standard? See the Cross-Domain Ratio Lattice paper.<br><br></p> </li> <li> <p dir="ltr">Will you update the PDF? A minor v1.1 with a 1-page front note (and Tu where needed) is planned.</p> </li> </ul> <p><strong></strong>This paper presents a resonance-based resolution of the black hole information paradox through the framework of Cosmic Algorithm Theory (CAT-12). Traditionally, black holes are viewed as paradoxical objects that both destroy and conserve information, raising deep questions about the nature of quantum mechanics, relativity, and thermodynamics.</p> <p> </p> <p>We reframe the event horizon not as a site of annihilation but as a resonance boundary and critical transition surface, where matter and information undergo ratio compression. Using CAT-12’s ratio lattices, resonance ladders, and phase-change analysis, the work models spaghettification as the convergence of matter’s harmonics into invariant mathematical ratios. Information, rather than being lost, is mathematically transmuted into stable resonance structures, functionally equivalent to holographic encoding.</p> <p> </p> <p>The results suggest that black holes act as custodians of invariants within the twelve-fold lattice of the universe, preserving order across cosmic cycles. This perspective bridges astrophysical theory, resonance mathematics, and philosophy, offering a new interpretation of how information persists at the edge of spacetime.</p> <p> </p> <p>Keywords: black holes, information paradox, event horizon, Cosmic Algorithm Theory (CAT-12), resonance, holography, spaghettification, invariants</p>