Long-Time Equilibration Can Determine Transient Thermality

IF 9.3 Q1 PHYSICS, APPLIED PRX quantum : a Physical Review journal Pub Date : 2022-12-01 DOI:10.1103/PRXQuantum.4.030321

K. Hovhannisyan, S. Nemati, C. Henkel, J. Anders

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引用次数: 1

Abstract

When two initially thermal many-body systems start interacting strongly, their transient states quickly become non-Gibbsian, even if the systems eventually equilibrate. To see beyond this apparent lack of structure during the transient regime, we use a refined notion of thermality, which we call g-local. A system is g-locally thermal if the states of all its small subsystems are marginals of global thermal states. We numerically demonstrate for two harmonic lattices that whenever the total system equilibrates in the long run, each lattice remains g-locally thermal at all times, including the transient regime. This is true even when the lattices have long-range interactions within them. In all cases, we find that the equilibrium is described by the generalized Gibbs ensemble, with three-dimensional lattices requiring special treatment due to their extended set of conserved charges. We compare our findings with the well-known two-temperature model. While its standard form is not valid beyond weak coupling, we show that at strong coupling it can be partially salvaged by adopting the concept of a g-local temperature.

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长时间的平衡可以确定瞬态热

当两个最初的热多体系统开始强烈相互作用时，即使系统最终达到平衡，它们的瞬态也会迅速变成非吉布斯态。为了超越这种在瞬态状态下明显缺乏结构的现象，我们使用了一个精细的热概念，我们称之为g局域热。如果一个系统的所有小子系统的状态都是全局热状态的边缘，那么这个系统就是g局部热的。我们用数值方法证明了两个谐波晶格，无论何时整个系统在长期内达到平衡，每个晶格在任何时候都保持g局部热，包括瞬态状态。即使当晶格内部有长程相互作用时也是如此。在所有情况下，我们发现平衡是由广义吉布斯系综描述的，三维晶格由于其扩展的守恒电荷集而需要特殊处理。我们将我们的发现与众所周知的双温度模型进行了比较。虽然它的标准形式在弱耦合之外是无效的，但我们表明，在强耦合下，通过采用g局部温度的概念可以部分地挽救它。

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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