[Research 10] A Complementary Interpretation of Classical Physical Theories through Electromagnetic Rotational Resonance

Modern physics has achieved high predictive power and computational success across domains such as electromagnetism, thermodynamics, quantum mechanics, and relativity; however, it remains limited in providing a continuous and unified interpretation of the origins of electrons, temperature, energy, and matter. This study proposes electromagnetic rotational resonance as a complementary interpretive framework to address these explanatory gaps, aiming not to replace existing physical theories but to preserve their established results while extending their ontological meaning. Rather than presupposing the electron as a priori fundamental, this work interprets it as the outcome of materialization arising from the stabilization and confinement of rotational resonance under specific electromagnetic and thermal conditions, while temperature is redefined as a physical quantity reflecting the degree of deviation from an absolute reference resonance state. From this perspective, electromagnetic fields, thermodynamic temperature, quantum wave behavior, and relativistic physical quantities are not independent constructs but distinct expressions of a single continuous physical process. Finally, the significance of this interpretation as an integrative framework linking microscopic physics with macroscopic cosmology, along with its potential theoretical and empirical extensions, is discussed.