Stretched-exponential melting of a dynamically frozen state under imprinted phase noise in the ising chain in a transverse field

IF 1.6 4区 物理与天体物理 Q3 PHYSICS, CONDENSED MATTER The European Physical Journal B Pub Date : 2024-09-09 DOI:10.1140/epjb/s10051-024-00776-3
Krishanu Roychowdhury, Arnab Das
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Abstract

The concept of dynamical freezing is a phenomenon where a suitable set of local observables freezes under a strong periodic drive in a quantum many-body system. This happens because of the emergence of approximate but perpetual conservation laws when the drive is strong enough. In this work, we probe the resilience of dynamical freezing to random perturbations added to the relative phases between the interfering states (elements of a natural basis) in the time-evolving wave function after each drive cycle. We study this in an integrable Ising chain in a time-periodic transverse field. Our key finding is, that the imprinted phase noise melts the dynamically frozen state, but the decay is “slow”: a stretched-exponential decay rather than an exponential one. Stretched-exponential decays (also known as Kohlrausch relaxation) are usually expected in complex systems with time-scale hierarchies due to strong disorders or other inhomogeneities resulting in jamming, glassiness, or localization. Here we observe this in a simple translationally invariant system dynamically frozen under a periodic drive. Moreover, the melting here does not obliterate the entire memory of the initial state but leaves behind a steady remnant that depends on the initial conditions. This underscores the stability of dynamically frozen states.

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横向场中等化链的印记相位噪声下动态冻结态的拉伸-指数熔化
摘要 动态冻结的概念是指在量子多体系统中,一组合适的局部观测值在强周期驱动下冻结的现象。这是因为当驱动力足够强时,会出现近似但永久的守恒定律。在这项研究中,我们探究了动态冻结对随机扰动的适应性,这些随机扰动被添加到每个驱动周期后时间演化波函数中干涉态(自然基的元素)之间的相对相位上。我们在时间周期横向场中的可积分伊辛链中研究了这一问题。我们的主要发现是,印记相位噪声融化了动态冻结态,但衰变 "缓慢":是拉伸指数衰变,而不是指数衰变。拉伸指数衰减(也称为科劳施弛豫)通常出现在具有时间尺度层次结构的复杂系统中,这是由于强烈的紊乱或其他不均匀性导致了干扰、玻璃化或局部化。在这里,我们在一个周期性驱动下动态冻结的简单平移不变系统中观察到了这种情况。此外,这里的熔化并没有抹去初始状态的全部记忆,而是留下了取决于初始条件的稳定残余。这强调了动态冻结状态的稳定性。
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来源期刊
The European Physical Journal B
The European Physical Journal B 物理-物理:凝聚态物理
CiteScore
2.80
自引率
6.20%
发文量
184
审稿时长
5.1 months
期刊介绍: Solid State and Materials; Mesoscopic and Nanoscale Systems; Computational Methods; Statistical and Nonlinear Physics
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