Related papers: Thermalization and irreversibility of an isolated quantum system II

Thermalization and irreversibility of an isolated quantum system II

URL: http://arxiv.org/abs/2506.01351v4
Date: Thu, 19 Jun 2025 08:10:10 GMT
Title: Thermalization and irreversibility of an isolated quantum system II
Authors: Xue-Yi Guo,
Abstract summary: We numerically demonstrate irreversible growth of entanglement entropy caused by erasure of spread non-equilibrium state information.<n>Our work demonstrates that the second law of thermodynamics, and consequently the ergodic hypothesis in statistical physics, can be understood and proven from a quantum information perspective.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The irreversible entropy increase described by the second law of thermodynamics is fundamentally tied to thermalization and the emergence of equilibrium. In the first part of our work (Ref: arXiv.2503.04152), we constructed an isolated gas system model and numerically demonstrated irreversible growth of entanglement entropy caused by erasure of spread non-equilibrium state information. Here, we mathematically prove that for a typical macroscopic system in a non-equilibrium state $|\phi_0\rangle$, the quantum state $|\phi'_0\rangle = \hat{O}(t)|\phi_0\rangle$ will inevitably evolve toward equilibrium. Our work demonstrates that the second law of thermodynamics, and consequently the ergodic hypothesis in statistical physics, can be understood and proven from a quantum information perspective. From this perspective, the second law can be stated as: In typical macroscopic physical systems, the spreading and erasure of non-equilibrium information is inevitable.

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