Abstract:This paper establishes a novel formulation of gravity by reinterpreting gravitational intersection not as an immutable consequence of mass-centric spacetime curvature, but as a deterministic projection of localized spin-wavelengths and angular velocity resonance. Departing from traditional reliance on cumulative mass density, we demonstrate that the geometric parameters of both macro-celestial systems and micro-quantum domains can be systematically unified under a single, coherent mechanical identity. Through the empirical validation of planetary orbital metrics, this study confirms a strict adherence to a non-local electromagnetic resonance model, specifically mapping the core angular velocities of planetary bodies against spatial resonance nodes. Furthermore, by introducing the Quantuniverse (Qu) metric, we successfully establish a quantitative bridge between the hyper-high frequencies of quantum spin diagnostics (NMR/ESR) and the macro-rotational intervals of celestial structures, completing a multiscale framework across physical domains. The practical implications of this model open plausible, long-term horizons for next-generation aerospace architecture through the Miniaturized Earth Project. Utilizing a programmable 1 Qu core framework theoretically allows for the artificial induction of a stable 1 g environment within a compact structural radius, bypassing traditional engineering constraints. This frequency-driven understanding of the cosmos reframes the boundaries of interdisciplinary non-local physics and offers a rigorous, quantifiable trajectory for future space exploration industries.
Seongwon Choi (Wed,) studied this question.