Certifying Quantum Temporal Correlation via Randomized Measurements: Theory and Experiment
Abstract
We consider the certification of temporal quantum correlations using the pseudo-density matrix (PDM), an extension of the density matrix to the time domain, where negative eigenvalues are key indicators of temporal correlations. Conventional methods for detecting these correlations rely on PDM tomography, which often involves excessive redundant information and requires exponential resources. In this work, we develop an efficient protocol for temporal correlation detection by virtually preparing the PDM within a single time slice and estimating its second-order moments using randomized measurements. Through sample complexity analysis, we demonstrate that our protocol requires only a constant number of measurement bases, making it particularly advantageous for systems utilizing ensemble average measurements, as it maintains constant runtime complexity regardless of the number of qubits. We experimentally validate our protocol on a nuclear magnetic resonance platform, a typical thermodynamic quantum system, where the experimental results closely align with theoretical predictions, confirming the effectiveness of our protocol.
Cite
@article{arxiv.2409.02470,
title = {Certifying Quantum Temporal Correlation via Randomized Measurements: Theory and Experiment},
author = {Hongfeng Liu and Zhenhuan Liu and Shu Chen and Xinfang Nie and Xiangjing Liu and Dawei Lu},
journal= {arXiv preprint arXiv:2409.02470},
year = {2025}
}
Comments
19 pages, 11 figures, comments are welcome