Entropy Field Structure and the Recursive Collapse of the Electron: A Thermodynamic Foundation for Quantum Behavior

Conventional quantum mechanics treats the electron as a point-like particle endowed with intrinsic properties — mass, charge, and spin — that are inserted as axioms rather than derived from first principles. Here, we propose a thermodynamic reformulation of the electron grounded in entropy field dynamics, based on S-Theory. In this framework, the electron is composed of three distinct entropic components: Score (a collapsed entropy core from mass), S_EM (a structured electromagnetic entropy field from charge), and Sthermal (a diffuse entropy component from ambient interactions). We show that spin emerges as a rotating S_EM shell around Score, and that electron collapse — as in quantum measurement — can be modeled as a Recursive Amplification of Sfield (RAS) process driven by entropic feedback. Through mathematical formulation and high-resolution simulations, we demonstrate how the S-field components evolve under entropic excitation, culminating in a collapse threshold defined by local entropy density matching. This model not only explains the emergence of quantum properties but also offers a thermodynamic mechanism for electron–photon interaction, wavefunction collapse, and spin generation — revealing the inner structure and dynamics of one of nature’s most fundamental particles.