单元电路中来自守恒超运算器的非普遍性

Marco Lastres, Frank Pollmann, Sanjay Moudgalya
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引用次数: 0

摘要

量子控制理论中的一个重要结果是 2 美元局部单元门的 "普遍性",即由 L 美元量子单元组成的系统的任何全局单元演化都可以通过组成 2 美元局部单元门来实现。令人惊讶的是,最近的研究结果表明,在存在对称性的情况下,普遍性可能会被打破:一般来说,并非所有的全局对称单元都能用 $k$ 局部对称单元门来构造。这也限制了对称局部汉密尔顿所能实现的动力学。在本文中,我们表明在这种情况下,普遍性的障碍一般可以从与受限门集的单元演化相关的超算子对称性来理解。这些超算子对称性导致了算子希尔伯特空间的块分解,决定了算子空间的连通性,进而决定了动态李代数的结构。我们利用换元代数框架从门结构中系统地推导出超算子对称性,在几个例子中明确地证明了这一点,换元代数框架已被用于系统地推导其他量子多体系统中的对称性。我们清楚地划分了源于超算子对称性不同结构的两种不同类型的非普遍性,并讨论了其在物理观测中的特征。总之,我们的工作建立了一个全面的框架来探索单元电路的普遍性,并推导出其不存在的物理后果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Non-Universality from Conserved Superoperators in Unitary Circuits
An important result in the theory of quantum control is the "universality" of $2$-local unitary gates, i.e. the fact that any global unitary evolution of a system of $L$ qudits can be implemented by composition of $2$-local unitary gates. Surprisingly, recent results have shown that universality can break down in the presence of symmetries: in general, not all globally symmetric unitaries can be constructed using $k$-local symmetric unitary gates. This also restricts the dynamics that can be implemented by symmetric local Hamiltonians. In this paper, we show that obstructions to universality in such settings can in general be understood in terms of superoperator symmetries associated with unitary evolution by restricted sets of gates. These superoperator symmetries lead to block decompositions of the operator Hilbert space, which dictate the connectivity of operator space, and hence the structure of the dynamical Lie algebra. We demonstrate this explicitly in several examples by systematically deriving the superoperator symmetries from the gate structure using the framework of commutant algebras, which has been used to systematically derive symmetries in other quantum many-body systems. We clearly delineate two different types of non-universality, which stem from different structures of the superoperator symmetries, and discuss its signatures in physical observables. In all, our work establishes a comprehensive framework to explore the universality of unitary circuits and derive physical consequences of its absence.
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