This study proposes that heat, motion, waves, magnetism, and the mechanical properties of matter—traditionally treated as distinct phenomena in conventional physics—can be understood as manifestations derived from a common response structure: phase transitions of resonance. We redefine absolute zero (0 K) not as an endpoint of energy extinction but as a primordial state of contraction pressure, and we characterize resonance operating on this background not as matter or energy but as an ordering principle of state. The phase of resonance undergoes a continuous progression—fixation, relaxation, and escape—depending on environmental conditions. We analyze, in a stepwise manner, how these phase transitions are observed as the emergence of heat, translation and rotation, wave–particle character, magnetic ordering, phase transitions of matter, and energetic expressions. Through this phase-based framework, we present an integrated mechanical structure that traverses micro- and macroscopic regimes, and we argue that a conceptual shift toward resonance as an environmental order can motivate a unified reinterpretation across physics.
DEOKHO JEON (Wed,) studied this question.