Thermodynamic hierarchical equations of motion and their application to Carnot engine

arXiv - PHYS - Statistical Mechanics Pub Date : 2024-08-05 DOI:arxiv-2408.02249

Shoki Koyanagi, Yoshitaka Tanimura

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Abstract

We developed a computer code for the thermodynamic hierarchical equations of motion (T-HEOM) derived from a spin subsystem coupled to multiple Drude baths at different temperatures, which are connected to or disconnected from the subsystem as a function of time. The code can simulate the reduced dynamics of the subsystem under isothermal, isentropic, thermostatic, and entropic conditions. The thermodynamic extensive and intensive variables were calculated as physical observables, and the Gibbs and Helmholtz energies were evaluated as intensive and extensive work. The contribution of energies from the system-bath interaction was evaluated separately from the subsystem using the hierarchical elements of T-HEOM. The accuracy of the calculated results for the equilibrium distribution and two-body correlation functions of the subsystem was verified by comparison with the results obtained from the time-convolution-less Redfield equation. Non-Markovian effects in thermostatic processes were investigated by sequentially turning on and off the baths of different temperatures with different switching times and system-bath coupling. As a demonstration, a comparison was made by simulating the case where the temperature of one bath was varied over time and the case where similar temperature changes were achieved by turning on and off the baths at different temperatures. In addition, the Carnot engine was simulated under quasi-static conditions. To analyze the work done for the subsystem in the cycle, thermodynamic work diagrams were plotted as functions of intensive and extensive variables. The C++ source codes are provided as supplementary material.

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热力学分层运动方程及其在卡诺发动机中的应用

我们开发了一种热力学分层运动方程（T-HEOM）的计算机代码，该热力学分层运动方程是由一个自旋子系统与多个不同温度的德鲁德水浴耦合而得出的。该代码可以模拟子系统在等温、等熵、恒温和内熵条件下的还原动力学。热力学广义变量和集约变量作为物理观测变量进行计算，吉布斯能量和亥姆霍兹能量作为集约功和广义功进行评估。利用 T-HEOM 的分层元素，将系统与浴相互作用的能量贡献与子系统分开评估。子系统的平衡分布和双体相关函数的计算结果的准确性通过与无时间卷积雷德菲尔德方程的结果进行比较得到了验证。通过不同的开关时间和系统-水浴耦合，连续开启和关闭不同温度的水浴，研究了恒温过程中的非马尔可夫效应。作为演示，模拟了一个浴槽的温度随时间变化的情况和通过开启和关闭不同温度的浴槽实现类似温度变化的情况。此外，还在准静态条件下模拟了卡诺发动机。为了分析循环中子系统所做的功，绘制了热力学功图，作为密集变量和广泛变量的函数。C++ 源代码作为补充材料提供。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Statistical Mechanics

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