Demonstration of multi-time quantum statistics without measurement back-action

• URL: http://arxiv.org/abs/2207.06106v1
• Date: Wed, 13 Jul 2022 10:28:01 GMT
• Title: Demonstration of multi-time quantum statistics without measurement back-action
• Authors: Pengfei Wang, Hyukjoon Kwon, Chun-Yang Luan, Wentao Chen, Mu Qiao, Zinan Zhou, Kaizhao Wang, M. S. Kim and Kihwan Kim
• Abstract summary: It is challenging to obtain quantum statistics of multiple time points due to the principle of quantum mechanics that a measurement disturbs the quantum state. We propose an ancilla-assisted measurement scheme that does not suffer from the measurement-induced back-action.
• Score: 15.011381523485214
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: It is challenging to obtain quantum statistics of multiple time points due to the principle of quantum mechanics that a measurement disturbs the quantum state. We propose an ancilla-assisted measurement scheme that does not suffer from the measurement-induced back-action and experimentally demonstrate it using dual-species trapped ions. By ensemble averaging the ancilla-measurement outcomes with properly chosen weights, quantum statistics, such as quantum correlation functions and quasi-probability distributions can be reconstructed. We employ $^{171}\rm{Yb}^+$-$^{138}\rm{Ba}^+$ ions as the system and the ancilla to perform multi-time measurements that consist of repeated initialization and detection of the ancilla state without effecting the system state. The two- and three-time quantum correlation functions and quasi-probability distributions are clearly revealed from experimental data. We successfully verify that the marginal distribution is unaffected by the measurement at each time and identify the nonclassicality of the reconstructed distribution. Our scheme can be applied for any $N$-time measurements of a general quantum process, which will be an essential tool for exploring properties of various quantum systems.

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