相互作用猝灭下的太阳爆发量子Ising模型:纠缠和初始态相干的作用

Akash Mitra, Shashi C. L. Srivastava
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引用次数: 1

摘要

研究了一个孤立二部量子系统在相互作用猝灭下的非平衡动力学,即太阳爆发量子Ising模型。该模型的前猝极限是两个非相互作用的可积系统,即横向伊辛链和有限数量的孤立量子比特。谱波动特性作为相互作用强度的函数,从泊松统计量转变为Wigner-Dyson统计量。我们选择了纠缠熵作为探针来研究猝灭后动力学中热化或缺乏热化的方法。在接近可积极限,线性熵表现出振荡行为,而在混沌极限,它饱和。随着时间演化发生器的混沌性质,我们表明了初始状态的相干性在决定热化性质方面所起的重要作用。我们进一步证明了这些发现是普遍的,用无序强度的无序$XXZ$模型代替伊辛环,使其处于多体局域相。
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Sunburst quantum Ising model under interaction quench: Entanglement and role of initial state coherence
We study the nonequilibrium dynamics of an isolated bipartite quantum system, the sunburst quantum Ising model, under interaction quench. The prequench limit of this model is two noninteracting integrable systems, namely a transverse Ising chain and finite number of isolated qubits. As a function of interaction strength, the spectral fluctuation property goes from Poisson to Wigner-Dyson statistics. We chose entanglement entropy as a probe to study the approach to thermalization or lack of it in postquench dynamics. In the near-integrable limit, as expected, the linear entropy displays oscillatory behavior, while in the chaotic limit it saturates. Along with the chaotic nature of the time evolution generator, we show the importance of the role played by the coherence of the initial state in deciding the nature of thermalization. We further show that these findings are general by replacing the Ising ring with a disordered $XXZ$ model with disorder strength putting it in the many-body localized phase.
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