Spread and Spectral Complexity in Quantum Spin Chains: from Integrability to Chaos

arXiv - PHYS - Chaotic Dynamics Pub Date : 2024-05-18 DOI:arxiv-2405.11254

Hugo A. Camargo, Kyoung-Bum Huh, Viktor Jahnke, Hyun-Sik Jeong, Keun-Young Kim, Mitsuhiro Nishida

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Abstract

We explore spread and spectral complexity in quantum systems that exhibit a transition from integrability to chaos, namely the mixed-field Ising model and the next-to-nearest-neighbor deformation of the Heisenberg XXZ spin chain. We corroborate the observation that the presence of a peak in spread complexity before its saturation, is a characteristic feature in chaotic systems. We find that, in general, the saturation value of spread complexity post-peak depends not only on the spectral statistics of the Hamiltonian, but also on the specific state. However, there appears to be a maximal universal bound determined by the symmetries and dimension of the Hamiltonian, which is realized by the thermofield double state (TFD) at infinite temperature. We also find that the time scales at which the spread complexity and spectral form factor change their behaviour agree with each other and are independent of the chaotic properties of the systems. In the case of spectral complexity, we identify that the key factor determining its saturation value and timescale in chaotic systems is given by minimum energy difference in the theory's spectrum. This explains observations made in the literature regarding its earlier saturation in chaotic systems compared to their integrable counterparts. We conclude by discussing the properties of the TFD which, we conjecture, make it suitable for probing signatures of chaos in quantum many-body systems.

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量子自旋链的扩散和谱复杂性：从整体性到混沌

我们探讨了量子系统（即混合场伊辛模型和海森堡 XXZ 自旋链的近邻变形）中的扩散和谱复杂性，这些系统表现出从可整性到混沌的过渡。我们证实了一个观察结果，即扩散复杂性在饱和之前出现峰值是混沌系统的一个特征。我们发现，一般来说，峰值后的扩散复杂性饱和值不仅取决于哈密顿的谱统计，还取决于特定的状态。然而，似乎存在一个由哈密顿对称性和维度决定的最大普遍边界，它由无限温度下的热场双态（TFD）实现。我们还发现，扩散复杂性和光谱形式因子改变其行为的时间尺度彼此一致，并且与系统的混沌特性无关。就频谱复杂性而言，我们发现决定其在混沌系统中的饱和值和时间尺度的关键因素是理论频谱中的最小能量差，这解释了文献中关于其在混沌系统中比在可积分系统中更早饱和的观察结果。最后，我们讨论了 TFD 的特性，我们推测这些特性使 TFD 适合于探测量子多体系统中的混沌特征。

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 - Chaotic Dynamics

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