Asymptotic phase-locking and synchronization in two-qubit systems

IF 1.1 Q3 PHYSICS, MULTIDISCIPLINARY

Journal of Physics Communications Pub Date : 2022-10-13 DOI:10.1088/2399-6528/acc0d4

Daniel Štěrba, J. Novotny, I. Jex

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引用次数: 2

Abstract

The paper concerns spontaneous asymptotic phase-locking and synchronization in two-qubit systems undergoing continuous Markovian evolution described by Lindbladian dynamics with normal Lindblad operators. Using analytic methods, all phase-locking-enforcing mechanisms within the given framework are obtained and classified. Detailed structures of their respective attractor spaces are provided and used to explore their properties from various perspectives. Amid phase-locking processes those additionally enforcing identical stationary parts of both qubits are identified, including as a special case the strictest form of synchronization conceivable. A prominent basis is presented which reveals that from a physical point of view two main types of phase-locking mechanisms exist. The ability to preserve information about the initial state is explored and an upper bound on the amplitude of oscillations of the resulting phase-locked dynamics is established. Permutation symmetry of both asymptotic states and phase-locking mechanisms is discussed. Lastly, the possibility of entanglement production playing the role of a phase-locking witness is rebutted by three analytically treatable examples.

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双量子位系统的渐近锁相与同步

本文研究了由Lindbladian动力学描述的具有正常Lindblad算子的连续马尔可夫演化的双量子位系统的自发渐近锁相和同步问题。利用解析方法，得到了给定框架内所有锁相机制，并对其进行了分类。提供了它们各自吸引子空间的详细结构，并从不同的角度探索它们的性质。在锁相过程中，确定了那些额外强制两个量子位相同的固定部分，包括作为可以想象的最严格形式的同步的特殊情况。一个突出的基础显示，从物理的角度来看，锁相机制存在两种主要类型。探讨了保留初始状态信息的能力，并建立了锁相动力学振荡幅度的上界。讨论了渐近态和锁相机制的排列对称性。最后，用三个可解析处理的例子反驳了纠缠产生起到锁相见证作用的可能性。

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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