Universal dynamics and non-thermal fixed points in quantum fluids far from equilibrium

IF 2.6 3区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

European Physical Journal-special Topics Pub Date : 2023-09-12 DOI:10.1140/epjs/s11734-023-00974-7

Aleksandr N. Mikheev, Ido Siovitz, Thomas Gasenzer

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引用次数: 1

Abstract

Abstract Closed quantum systems far from thermal equilibrium can show universal dynamics near attractor solutions, known as non-thermal fixed points, generically in the form of scaling behaviour in space and time. A systematic classification and comprehensive understanding of such scaling solutions are tasks of future developments in non-equilibrium quantum many-body theory. In this tutorial review, we outline several analytical approaches to non-thermal fixed points and summarise corresponding numerical and experimental results. The analytic methods include a non-perturbative kinetic theory derived within the two-particle irreducible effective action formalism, as well as a low-energy effective field theory framework. As one of the driving forces of this research field are numerical simulations, we summarise the main results of exemplary cases of universal dynamics in ultracold Bose gases. This encompasses quantum vortex ensembles in turbulent superfluids as well as recently observed real-time instanton solutions in one-dimensional spinor condensates.

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远离平衡的量子流体中的普遍动力学和非热不动点

远离热平衡的封闭量子系统可以在吸引子解附近显示出普遍的动力学，被称为非热不动点，通常以空间和时间尺度行为的形式出现。对这些标度解的系统分类和全面理解是未来非平衡量子多体理论发展的任务。在本教程回顾中，我们概述了几种非热不动点的分析方法，并总结了相应的数值和实验结果。分析方法包括在两粒子不可约有效作用形式下导出的非微扰动力学理论，以及低能量有效场论框架。由于这一研究领域的驱动力之一是数值模拟，我们总结了超冷玻色气体中普遍动力学的典型案例的主要结果。这包括湍流超流体中的量子涡旋系综以及最近观察到的一维旋量凝聚体中的实时瞬时解。

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来源期刊

European Physical Journal-special Topics 物理-物理：综合

CiteScore

5.10

自引率

10.70%

发文量

313

审稿时长

3-8 weeks

期刊介绍： EPJ - Special Topics (EPJ ST) publishes topical issues which are collections of review-type articles or extensive, detailed progress reports. Each issue is focused on a specific subject matter of topical interest. The journal scope covers the whole spectrum of pure and applied physics, including related subjects such as Materials Science, Physical Biology, Physical Chemistry, and Complex Systems with particular emphasis on interdisciplinary topics in physics and related fields.