Certifying bipartite pure quantum states efficiently using untrusted devices

• URL: http://arxiv.org/abs/2306.07755v2
• Date: Thu, 12 Dec 2024 01:21:10 GMT
• Title: Certifying bipartite pure quantum states efficiently using untrusted devices
• Authors: Lijinzhi Lin, Zhenyu Chen, Xiaodie Lin, Zhaohui Wei,
• Abstract summary: It has been known that all bipartite pure quantum states can be certified by quantum self-testing.<n>Here, we prove that when the underlying Hilbert space dimension is known beforehand, an arbitrary $dtimes d$ bipartite pure state can be certified completely.<n>Compared with quantum self-testing, our protocols do not hinge on quantum nonlocality and are much more efficient.
• Score: 4.2297975934654986
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: It has been known that all bipartite pure quantum states can be certified by quantum self-testing, i.e., any such states can be pinned down completely based on the statistics produced by local quantum measurements. A notable feature of quantum self-testing is that the conclusions remain reliable even when the quantum measurements involved are untrusted, where quantum nonlocality is crucial. This necessitates that each party conducts at least two different quantum measurements to produce the desired correlation. Here, we prove that when the underlying Hilbert space dimension is known beforehand, which is very common in quantum experiments, an arbitrary $d\times d$ bipartite pure state can be certified completely (up to local unitaries) by a certain correlation generated with a single measurement setting on each party, where each measurement yields only $2d$ or even $d+1$ outcomes. We also prove the robustness of our protocols to quantum noises and experimental imperfections. Compared with quantum self-testing, our protocols do not hinge on quantum nonlocality and are much more efficient, yet they maintain the essential feature of not requiring additional assumptions about the quantum devices involved. This advancement could offer significant convenience when certifying bipartite quantum states using untrusted quantum devices in future quantum industries.

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