具有时间不等式的双量子比特量子系统认证

IF 2.9 2区物理与天体物理 Q2 Physics and Astronomy Physical Review A Pub Date : 2024-08-06 DOI:10.1103/physreva.110.022408

Chellasamy Jebarathinam, Gautam Sharma, Sk Sazim, Remigiusz Augusiak

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引用次数: 0

摘要

基于观测到的测量统计数据对量子设备进行自测试，是一种利用最少资源对量子系统进行认证的方法。在伊尔凡等人 [A. A. M. Irfan, K. Mayer, G. Ortiz, and E. Knill.A.M.Irfan、K.Mayer、G.Ortiz 和 E.Knill，Phys. Rev. A 101, 032106 (2020)]中展示了一种基于观测证明 Kochen-Specker 上下文性的测量统计量的方案，它可以认证双量子比特纠缠状态和测量，而不需要子系统之间的空间分离。然而，这一方案假设了一组测量的兼容性条件，而这些条件对于证明 Kochen-Specker 上下文相关性至关重要。在本文中，我们提出了一种自测试协议，在不假定兼容性条件的情况下认证上述双量子比特状态和测量，同时也不要求子系统之间的空间分离。我们的协议基于对顺序相关性的观测，这种观测会导致对非上下文不等式衍生出的时间不等式的最大违反。此外，我们的协议对微小的实验误差或噪音也具有鲁棒性。

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Certification of two-qubit quantum systems with temporal inequality

Self-testing of quantum devices based on observed measurement statistics is a method to certify quantum systems using minimal resources. In Irfan et al. [A. A. M. Irfan, K. Mayer, G. Ortiz, and E. Knill, Phys. Rev. A 101, 032106 (2020)] a scheme based on observing measurement statistics that demonstrate Kochen-Specker contextuality has been shown to certify two-qubit entangled states and measurements without the requirement of spatial separation between the subsystems. However, this scheme assumes a set of compatibility conditions on the measurements which are crucial to demonstrating Kochen-Specker contextuality. In this paper, we propose a self-testing protocol to certify the above two-qubit states and measurements without the assumption of the compatibility conditions, and at the same time without requiring the spatial separation between the subsystems. Our protocol is based on the observation of sequential correlations leading to the maximal violation of a temporal inequality derived from noncontextuality inequality. Moreover, our protocol is robust to small experimental errors or noise.

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来源期刊

Physical Review A 物理-光学

CiteScore

5.40

自引率

24.10%

发文量

审稿时长

2.2 months

期刊介绍： Physical Review A (PRA) publishes important developments in the rapidly evolving areas of atomic, molecular, and optical (AMO) physics, quantum information, and related fundamental concepts. PRA covers atomic, molecular, and optical physics, foundations of quantum mechanics, and quantum information, including: -Fundamental concepts -Quantum information -Atomic and molecular structure and dynamics; high-precision measurement -Atomic and molecular collisions and interactions -Atomic and molecular processes in external fields, including interactions with strong fields and short pulses -Matter waves and collective properties of cold atoms and molecules -Quantum optics, physics of lasers, nonlinear optics, and classical optics

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