Stark多体定位的实验探针

S. Taylor, M. Schulz, F. Pollmann, R. Moessner
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引用次数: 41

摘要

最近的工作集中在探索多体定位(MBL)系统中没有淬火无序:其中一个这样的建议是斯塔克MBL,其中小扰动强线性潜在屈服定位。然而,与传统的MBL一样,在实验上区分非相互作用定位和真正的MBL是具有挑战性的。在本文中,我们展示了几个现有的实验探针,专门设计用于区分这些场景,在Stark MBL设置中工作相似。我们特别指出,修正的自旋回波响应(DEER)在Stark MBL中显示出明显的幂律衰减迹象,而在无无序的wanner -Stark定位中则迅速饱和。此外,我们还观察到了Stark MBL体系中量子互信息的对数时域扩展特性,以及非相互作用的Stark局域系统中量子互信息的无扩展特性。我们还表明,对于具有排斥现场相互作用的软核玻色子组成的系统,几种现有的MBL测量没有显着差异。最后,我们说明了为什么曲率或小无序需要MBL现象学的精确再现,以及如何在实验中说明这一点。这也与具有守恒偶极矩的“分形”模型中希尔伯特空间碎片化的最新进展有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental probes of Stark many-body localization
Recent work has focused on exploring many-body localization (MBL) in systems without quenched disorder: one such proposal is Stark MBL in which small perturbations to a strong linear potential yield localization. However, as with conventional MBL, it is challenging to experimentally distinguish between non-interacting localization and true MBL. In this paper we show that several existing experimental probes, designed specifically to differentiate between these scenarios, work similarly in the Stark MBL setting. In particular we show that a modified spin-echo response (DEER) shows clear signs of a power-law decay for Stark MBL while quickly saturating for disorder-free Wannier-Stark localization. Further, we observe the characteristic logarithmic-in-time spreading of quantum mutual information in the Stark MBL regime, and an absence of spreading in a non-interacting Stark-localized system. We also show that there are no significant differences in several existing MBL measures for a system consisting of softcore bosons with repulsive on-site interactions. Lastly we show why curvature or small disorder are needed for an accurate reproduction of MBL phenomenology, and how this may be illustrated in experiment. This also connects with recent progress on Hilbert space fragmentation in ``fractonic'' models with conserved dipole moment.
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