Glassy word problems: ultraslow relaxation, Hilbert space jamming, and computational complexity

Shankar Balasubramanian, Sarang Gopalakrishnan, Alexey Khudorozhkov, Ethan Lake
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Abstract

We introduce a family of local models of dynamics based on ``word problems'' from computer science and group theory, for which we can place rigorous lower bounds on relaxation timescales. These models can be regarded either as random circuit or local Hamiltonian dynamics, and include many familiar examples of constrained dynamics as special cases. The configuration space of these models splits into dynamically disconnected sectors, and for initial states to relax, they must ``work out'' the other states in the sector to which they belong. When this problem has a high time complexity, relaxation is slow. In some of the cases we study, this problem also has high space complexity. When the space complexity is larger than the system size, an unconventional type of jamming transition can occur, whereby a system of a fixed size is not ergodic, but can be made ergodic by appending a large reservoir of sites in a trivial product state. This manifests itself in a new type of Hilbert space fragmentation that we call fragile fragmentation. We present explicit examples where slow relaxation and jamming strongly modify the hydrodynamics of conserved densities. In one example, density modulations of wavevector $q$ exhibit almost no relaxation until times $O(\exp(1/q))$, at which point they abruptly collapse. We also comment on extensions of our results to higher dimensions.
玻璃文字问题:超慢速松弛、希尔伯特空间干扰和计算复杂性
我们基于计算机科学和群论中的 "文字问题 "引入了一系列局部动力学模型,我们可以为这些模型设定严格的松弛时间尺度下限。这些模型既可视为随机电路动力学模型,也可视为局部哈密顿动力学模型,还包括许多我们熟悉的受约束动力学特例。这些模型的配置空间分裂成动态断开的扇区,初始态必须 "解决 "其所属扇区中的其他态才能松弛。在我们研究的某些情况下,这个问题的空间复杂度也很高。当空间复杂度大于系统大小时,就会出现一种非常规的干扰转换,即一个固定大小的系统不是遍历的,但可以通过在琐积状态中添加大量的位点库来使其成为遍历的。这表现为一种新型的希尔伯特空间碎片化,我们称之为脆弱碎片化。我们给出了一些明确的例子,在这些例子中,缓慢松弛和干扰强烈地改变了守恒性的流体力学。在其中一个例子中,波向量 $q$ 的密度调制在 $O(\exp(1/q))$ 时间之前几乎没有松弛,而在此时它们会突然坍缩。我们还评论了我们的结果在更高维度上的扩展。
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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