Myo Min Aung Unified Theory (MUT) v7.16: Ultimate Master Framework - A Complete Unified Field Theory From Nucleons to Cosmology

This work presents MUT v7. 16, the complete formulation of the Myo Min Aung Unified Theory, an n-free unified field framework based on the Mass Curvature Rate (fmcr) principle. The theory introduces a universal resonance scalar field Phi that modifies gravitational dynamics through a gradient-based acceleration term: a = aN + (c² / 2) * grad (Phi) This formulation provides a unified description of gravitational behavior across all physical scales, from nucleons to cosmology, while maintaining dimensional consistency and continuity with the proton-scale constant: fmcr = c / mp = 1. 792 × 10³5 m/ (kg·s). The framework is tested across multiple observational regimes. Galactic rotation curves are reproduced without invoking dark matter using baryonic mass distributions from the SPARC database. Cosmological predictions are evaluated using a modified Boltzmann solver for Cosmic Microwave Background anisotropies, producing a CMB power spectrum consistent with Planck 2018 observations with chi-square improvement relative to Lambda-CDM. Large-scale structure formation is investigated using N-body simulations based on a modified transfer function, showing deviations below 2 percent from standard cosmology across nonlinear scales. Gravitational lensing in the Bullet Cluster is reconstructed using the resonance field gradient profile, reproducing the observed convergence distribution without requiring collisionless dark matter. Primordial nucleosynthesis calculations with a time-evolving scalar field demonstrate that the resonance field remains extremely close to its ground state during the early universe, preserving standard Big Bang nucleosynthesis predictions for helium and deuterium abundances. The theory also addresses the Hubble constant tension by predicting: H0 = 69. 9 ± 0. 5 km/s/Mpcwhich lies between the Planck and SH0ES measurements and reduces the discrepancy from 5. 8 sigma to approximately 1. 1 sigma. A comprehensive Monte Carlo sensitivity analysis confirms the stability of the framework under parameter variations, while a micro-to-macro continuity analysis demonstrates consistent behavior across more than 80 orders of magnitude in mass. MUT v7. 16 therefore presents a unified gravitational framework in which a single resonance field governs phenomena traditionally attributed to dark matter and dark energy, providing testable predictions for upcoming cosmological surveys including Euclid, DESI, LiteBIRD, and next-generation gravitational observatories.