Many-Body Fluctuation Theorems for Quantum Coherence and Correlation Dynamics
Abstract
Fluctuation theorems establish exact relations for nonequilibrium dynamics, profoundly advancing the field of stochastic thermodynamics. In this Letter, we extend quantum fluctuation theorems beyond the traditional thermodynamic framework to quantum information dynamics and many-body systems, where both the system and the environment are multipartite without assuming any thermodynamic constraints. Based on the two-point measurement scheme and the classical probability, we establish the fluctuation theorem for the dynamics of many-body classical mutual information. By extending to quasiprobability, we derive quantum fluctuation theorems for many-body coherence and quantum correlations, presenting them in both integral and detailed forms. Our theoretical results are illustrated and verified using three-qubit examples, and feasible experimental verification protocols are proposed. These findings uncover the statistical structure underlying the nonequilibrium quantum information dynamics, providing fundamental insights and new tools for advancing quantum technologies.