Gravity-Consciousness Unified Theory
Description
The Gravity–Consciousness Unified Theory (GCUT), Version 2 (Addendum to Version 1), introduces dynamic scaling laws for universal constants—including the gravitational constant G, the speed of light c, and Planck energy E_P—modulated by a time-dependent scalar factor S(t). This scalar governs inflation–deflation cycles and links cosmic evolution with matter–antimatter annihilation and resonance phenomena, culminating in the Dual Bang model: an Exit Bang (inflation) and Annihilation Bang (reheating and structure emergence). A key feature of GCUT is the Resonance Frequency Waves (RFW)—a proposed substrate responsible for inter-universal coherence and non-local quantum correlations. RFWs underpin entanglement, gravitational memory, and the recursive structure of cosmic information, suggesting observational signatures such as residual wavefunction effects and anomalous gravitational wave backgrounds. This version introduces a unified GCUT+Standard Model Lagrangian and proposes a supersymmetric generalization (GCUT-SUSY), where time-varying gravitational scaling naturally triggers supersymmetry breaking. The theory offers testable predictions concerning the variation of fundamental constants, primordial black hole distributions (consistent with JWST observations), and gravitational wave relics from the Annihilation Bang. Philosophically, GCUT proposes that consciousness is an emergent and recursive property of gravity—encoded through multiversal resonance patterns and sustained via entropy-driven decoherence across cosmic cycles. In this view, gravity is reconceptualized not merely as a force but as a dynamic scaling field that governs creation, evolution, and stabilization across a recursive multiverse.
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Steps to reproduce
1. Theoretical Derivation: • Review the equations proposed in the paper, including scaling laws, inflation-deflation dynamics, and gravitational-energy relations. • Use symbolic computation software (e.g., Mathematica, SymPy, or MATLAB) to replicate mathematical derivations. 2. Numerical Simulations: • Implement the proposed equations using a programming language like Python, focusing on universal scaling, gravitational constants, and Planck energy fluctuations. • Initialize scaling factors and key variables as specified in the manuscript. 3. Experimental Concepts: • Simulate experimental conditions using high-energy collision models (as suggested for particle accelerators like the LHC) to explore matter-antimatter creation dynamics. • Consider testing gravitational anomalies using precision instruments such as quantum interferometers, where applicable. 4. Data Visualization: • Use visualization tools (e.g., Matplotlib, Excel) to plot the progression of theoretical constants, energy levels, and scaling dynamics. • Focus on creating time-based graphs that show inflation-deflation cycles and energy dynamics across successive universes. 5. Model Validation: • Compare computed results to established theories such as general relativity, quantum field theory, and inflationary cosmology. • Note deviations from standard models and analyze their implications in the context of the proposed theory. 6. Suggested Tools: • Software: Python, MATLAB, Mathematica • Libraries: NumPy, SciPy, Matplotlib, SymPy • References: Refer to foundational works in physics cited in the manuscript for theoretical comparison and validation frameworks.