Floquet dynamical chiral spin liquid at finite frequency

arXiv - PHYS - Strongly Correlated Electrons Pub Date : 2024-09-07 DOI:arxiv-2409.04892

Didier Poilblanc, Matthieu Mambrini, Nathan Goldman

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Abstract

Chiral Spin Liquids (CSL) are quantum spin analogs of electronic Fractional Chern Insulators. Their realizations on ultracold-atom or Rydberg-atom platforms remain very challenging. Recently, a setup of time-periodic modulations of nearest-neighbor Heisenberg couplings applied on an initial genuine spin liquid state on the square lattice has been proposed to stabilize a (Abelian) $\mathbb{Z}_2$ CSL phase. In the high-frequency limit, it was shown that time evolution can be described in terms of a static effective chiral Hamiltonian. Here we revisit this proposal and consider drives at lower frequency in a regime where the high-frequency Magnus expansion fails. We show that a Dynamical CSL (DCSL) is nevertheless stabilized in a finite range of frequency. The topological nature of this dynamical phase, as well as its instability below a critical frequency, is connected to specific features of the Floquet pseudo-energy spectrum. We also show that the DCSL can be represented faithfully by a two-dimensional time-periodic tensor network and, as in the static case, topological order is associated to a tensor gauge symmetry ($\mathbb{Z}_2$ in that case).

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有限频率下的 Floquet 动力手性自旋液体

手性自旋液体（CSL）是电子分数切恩绝缘体的量子自旋类似物。在超冷原子或雷德贝格原子平台上实现它们仍然非常具有挑战性。最近，有人提出了在方形晶格上的初始自旋液体态上应用最近邻海森堡耦合的时间周期调制来稳定（阿贝尔）$\mathbb{Z}_2$ CSL相。研究表明，在高频极限下，时间演化可以用一个静态有效的手性哈密顿来描述。在此，我们重新审视了这一提议，并考虑了在高频马格努斯扩展失效的情况下的低频驱动。我们证明，动态 CSL（DCSL）在有限的频率范围内是稳定的。这一动力学阶段的拓扑性质，以及它在临界频率以下的不稳定性，都与 Floquet 伪能谱的具体特征有关。我们还证明，二维时周期张量网络可以忠实地表示 DCSL，而且与静态情况一样，拓扑阶数与张量规对称性（在这种情况下为 $\mathbb{Z}_2$）相关。

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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arXiv - PHYS - Strongly Correlated Electrons

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