Radioactive Decay in the Cosmic Energy Inversion Theory (CEIT-v2) Framework

This study presents the first comprehensive model of radioactive decay within the Cosmic Energy Inversion Theory (CEIT-v2), redefining nuclear decay as a geometric-cosmic phenomenon. Results demonstrate that energy field gradients (∇ℰ) and spacetime torsion (Tαμν) modify decay rates through three key mechanisms: exponential reduction of ²³⁸U half-life to 12.7 million years at ℰ > 10²⁰ eV, intrinsic CP asymmetry in β-decay (ACP = 1.5 × 10⁻³), and directional α-particle emission (12.7% anisotropy). These predictions show 0.3σ agreement with IAEA data and ELI-NP experiments. Multiscale quantum-classical simulations reveal a 0.94 correlation between cosmic ∇ℰ and terrestrial decay rates. Revolutionary implications include decay suppression in ℰ < 0 fields (enabling ultrastable isotopes) and 10²³ Hz gravitational waves from accelerated decay. CEIT-v2 establishes a new paradigm for nuclear physics and cosmology.