Research 21 "Structural Isomorphism Between the Microscopic and Macroscopic Worlds Viewed Through Rotational Resonance Cosmology"

This study aims to bridge the discontinuous interpretations between microscopic material structure and macroscopic astrophysical systems by reinterpreting nuclear force and angular momentum not as intrinsic, independent forces of matter, but as emergent consequences of a contractive rotational order formed through resonance and the long-term inertial effects of magnetic fields. At the microscopic scale, neutrons are unstable in a free state but acquire stability within binding environments, and this concept of collective stability is shown to extend analogously to the macroscopic behavior of neutron stars and black holes. While black holes play a stabilizing role by concentrating and aligning mass and energy at galactic centers, neutron stars promote material fragmentation and recirculation through unstable rotation and high mobility. These macroscopic processes of fragmentation and circulation extend to the formation of interstellar matter, meteorites, the iron-dominated core of the Earth, and the distribution of iron oxide minerals, ultimately linking to the material foundations of habitable environments. Through a resonance-based rotational framework, this study proposes a structural isomorphism between microscopic material composition and macroscopic cosmic structures, offering an integrated interpretation of material evolution.