We present a first-principles derivation of a master equation that unifies quantum dynamics, thermal effects, and Riemannian geometry within a holomorphic framework. By extending the temporal parameter into the complex domain = t + i2kB T, we demonstrate that the KMS condition in thermal field theory necessitates a specific form of evolution. We correct previous dimensional inconsistencies and derive the unique coupling constant = G / c, which links the Laplace-Beltrami operator to complex time evolution. The resulting Complex Time Quantum Thermal Geometric (CTQTG) equation predicts gravity-induced decoherence and a fundamental ultraviolet regularization of momentum states at finite temperatures.
Y. Li (Fri,) studied this question.