This work introduces Symbolic Field Interaction Topology (SFIT), a unified thermodynamic framework that extends classical statistical mechanics to incorporate topological and symbolic degrees of freedom alongside conventional thermal entropy. Starting from a microscopic substrate action involving braid variables and phase fields, the author derives a generalized First Law of Thermodynamics: \ U = T₄₅₅\, S₄₍ₓ - T₄₅₅ₓ₎\, Qₓ₎ + \, Pₒₘ₌, \ (S₄₍ₓ\), \ (Qₓ₎\), and \ (Pₒₘ₌\) represent thermal, topological, and symbolic contributions, respectively. An extended Second Law governs the coupled production of all three entropy types, with bounds on inter-sector conversion. The framework is validated through large-scale Monte Carlo simulations of the 2D Ising model, where topological observables—computed via persistent homology (Betti number ratios \ (R₁₁, R₁₂, R₁₄\) ) —precisely detect the critical point (\ (c = 0. 440 0. 002\) ) with **0. 16% relative error compared to the exact Onsager solution, without fitting thermal parameters. Additionally, the formalism is applied to the 2D XY model near the Kosterlitz–Thouless transition, providing operational definitions for the topological potential \ (ₓ₎\) and protocols for its numerical estimation. The paper also outlines experimental realizations in spin ice, BEC vortex systems, and DNA hairpin pulling experiments, and discusses connections to topological field theory, stochastic thermodynamics, and information theory. Reference Python implementations for XY model simulations and topological charge measurement are included in the appendix. This repository contains the complete manuscript (PDF) and serves as a foundational reference for SFIT—a thermodynamic language for systems where topology and information act as dynamical, energetic degrees of freedom.
Luiz PUODZIUS (Sat,) studied this question.