量子霸权和量子相变

Supanut Thanasilp, J. Tangpanitanon, M. Lemonde, Ninnat Dangniam, D. Angelakis
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引用次数: 4

摘要

展示现有量子平台执行经典计算机难以处理的某些计算任务的能力是量子计算的基石。尽管提出了越来越多的“量子至上”任务,但确定它们的直接应用仍然是一个重要的挑战。在这项工作中,我们描述了在Ref. [arXiv:2002.11946]中提出的方法如何在一般驱动的模拟多体系统中证明量子霸权,例如在冷原子和离子设置中发现的系统,可以扩展到探索动态量子相变。我们展示了关键的量子霸权签名,如输出分布与霸权制度下预期波特托马斯分布之间的距离,如何用作有效的顺序参数。我们将这种方法应用于周期性驱动的无序一维Ising模型,并表明我们可以准确地捕获驱动的热化相和多体局部化相之间的转变。这种方法也抓住了向高频驱动的Floquet预热状态的过渡。根据最近关于量子霸权的讨论,重新审视物质的量子相,将复杂性理论与模拟多体系统联系起来。
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Quantum supremacy and quantum phase transitions
Demonstrating the ability of existing quantum platforms to perform certain computational tasks intractable to classical computers represents a cornerstone in quantum computing. Despite the growing number of such proposed "quantum supreme" tasks, it remains an important challenge to identify their direct applications. In this work, we describe how the approach proposed in Ref. [arXiv:2002.11946] for demonstrating quantum supremacy in generic driven analog many-body systems, such as those found in cold atom and ion setups, can be extended to explore dynamical quantum phase transitions. We show how key quantum supremacy signatures, such as the distance between the output distribution and the expected Porter Thomas distribution at the supremacy regime, can be used as effective order parameters. We apply this approach to a periodically driven disordered 1D Ising model and show that we can accurately capture the transition between the driven thermalized and many-body localized phases. This approach also captures the transition towards the Floquet prethermalized regime for high-frequency driving. Revisiting quantum phases of matter under the light of the recent discussions about quantum supremacy draws a link between complexity theory and analog many-body systems.
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