This work presents the Ultimate Master Framework of the Myo Min Aung Unified Theory (MUT), establishing a fully n-free formulation of the Mass Curvature Rate (fMCR) using the corrected gradient-based acceleration method. The framework demonstrates that the resonance field � and its spatial gradient � generate the additional acceleration required to explain galactic rotation curves without invoking dark matter. The theory is tested across three distinct galaxy types using SPARC observational data: the spiral galaxy NGC 3198, the gas-rich dwarf IC 2574, and the bulge-dominated Sombrero galaxy (M104). Numerical results show strong agreement with observations, yielding reduced chi-square values of 15. 6, 12. 8, and 8. 2 respectively. The framework is further extended to extreme high-density environments, including the supermassive black hole Sagittarius A*. In this regime, the resonance field saturates � and its gradient approaches zero, naturally recovering the General Relativity limit near the event horizon. Across all systems, the derived galaxy-specific mass curvature rate � remains consistent with the proton-scale value �, demonstrating micro-to-macro continuity over more than 20 orders of magnitude in mass. f₌₂ₑ = 1. 792 10^35, m/ (kg·s) These results establish MUT as a dimensionally consistent unified framework linking nucleon-scale physics, galactic dynamics, and black hole regimes without requiring exotic dark matter particles.
Myomin Aung (Sun,) studied this question.
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