Published March 7, 2025 | Version V1.0

CHRONOS: A Unified Framework for Time Force Dynamics in Black Hole Physics Quantum Teleportation and Beyond

Description

This paper presents the CHRONOS framework (Chrono-Harmonic Relativity of Nonlinear Oscillatory Systems), a novel approach to understanding time as an active force rather than a passive dimension. The CHRONOS model introduces structured time-force oscillations, offering a unified mathematical framework that applies to:

  • Black Hole Information Conservation: CHRONOS suggests that time behaves dynamically near event horizons, leading to periodic entropy oscillations that prevent absolute information loss. Observational tests using X-ray and gamma-ray spectra are proposed.
  • Quantum Teleportation Enhancement: By modulating entanglement stability, CHRONOS introduces high-fidelity synchronization windows, improving long-distance quantum communication and reducing decoherence effects.
  • Energy Storage Optimization: CHRONOS-driven oscillations provide a mechanism for extended energy retention in quantum batteries and superconductors, mitigating dissipative losses.
  • Faster-Than-Light (FTL) Travel: The framework explores the potential for stabilizing Alcubierre warp metrics by oscillating spacetime curvature, potentially reducing the negative energy density requirement.

This work bridges general relativity, quantum mechanics, and quantum information science, providing a testable approach to some of the most fundamental questions in physics. Future research includes laboratory validation using Bose-Einstein condensates, quantum optics experiments, and astrophysical data analysis.

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CHRONOS__A_Unified_Framework_for_Time_Force_Dynamics_in_Black_Hole_Physics__Quantum_Teleportation__and_Beyond.pdf

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References

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