Edge Modes and Symmetry-Protected Topological States in Open Quantum Systems

Dawid Paszko, Dominic C. Rose, Marzena H. Szymańska, Arijeet Pal
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Abstract

Topological order offers possibilities for processing quantum information that can be immune to imperfections. However, the question of its stability out of equilibrium is relevant for experiments, where coupling to an environment is unavoidable. In this work, we demonstrate the robustness of certain aspects of Z2×Z2 symmetry-protected topological (SPT) order against a wide class of dissipation channels in the Lindblad and quantum trajectory formalisms of an open quantum system. This is illustrated using the one-dimensional ZXZ cluster Hamiltonian along with Pauli-string jump operators. We show that certain choices of dissipation retaining strong symmetries support a steady-state manifold consisting of two nonlocal logical qubits and for Hamiltonian perturbations preserving the global symmetry, states in this manifold remain metastable. In contrast, this metastability is destroyed upon breaking the above-mentioned symmetry. While the localized edge qubits of the cluster Hamiltonian are not conserved by the Lindbladian evolution, they do correspond to weak symmetries and thus retain a memory of their initial state at all times in the quantum trajectories. We utilize this feature to construct protocols to retrieve the quantum information either by monitoring jumps or error mitigation. Our work thus proposes a novel framework to study the dynamics of dissipative SPT phases and opens up the possibility of engineering entangled states relevant to quantum information processing.

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开放量子体系中的边缘模和受对称保护的拓扑状态
拓扑秩序为处理量子信息提供了可能性,它可以不受不完美因素的影响。然而,在与环境耦合不可避免的情况下,平衡状态之外的稳定性问题与实验息息相关。在这项工作中,我们证明了 Z2×Z2 对称保护拓扑(SPT)秩的某些方面在开放量子系统的林德布拉德和量子轨迹形式中对各种耗散通道的稳健性。我们用一维 ZXZ 簇哈密顿和保利弦跃迁算子来说明这一点。我们表明,某些保留强对称性的耗散选择支持由两个非局部逻辑量子比特组成的稳态流形,而对于保留全局对称性的哈密顿扰动,该流形中的状态仍然是可转移的。相反,一旦打破上述对称性,这种可变性就会被破坏。虽然集群哈密顿的局部边缘量子比特不受林布拉德演化的保护,但它们确实与弱对称性相对应,因此在量子轨迹中始终保持着对其初始状态的记忆。我们利用这一特点构建协议,通过监测跳跃或减少错误来检索量子信息。因此,我们的工作提出了一个研究耗散 SPT 相动态的新框架,并为量子信息处理相关的纠缠态工程开辟了可能性。
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