Related papers: Quantum metrology with one auxiliary particle in a correlated bath and its quantum simulation

Quantum metrology with one auxiliary particle in a correlated bath and its quantum simulation

URL: http://arxiv.org/abs/2105.10260v1
Date: Fri, 21 May 2021 10:24:36 GMT
Title: Quantum metrology with one auxiliary particle in a correlated bath and its quantum simulation
Authors: Wan-Ting He, Huan-Yu Guang, Zi-Yun Li, Ru-Qiong Deng, Na-Na Zhang, Jie-Xing Zhao, Fu-Guo Deng, and Qing Ai
Abstract summary: The precision of parameter estimation with entangled probes is even lower than that of the unentangled ones in a correlated environment. We propose a measurement scheme with only one auxiliary qubit, which can selectively offset the impact of environmental noise.
Score: 1.0118253437732931
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In realistic metrology, entangled probes are more sensitive to noise, especially for a correlated environment. The precision of parameter estimation with entangled probes is even lower than that of the unentangled ones in a correlated environment. In this paper, we propose a measurement scheme with only one auxiliary qubit, which can selectively offset the impact of environmental noise under this situation. We analyse the estimation precision of our scheme and find out that it approaches the Heisenberg limit when prepared in a proper auxiliary state. We further discuss employing auxiliary states to improve the precision of measurement in other environment models such as a partially-correlated environment. In order to verify our scheme, we apply a recently-developed quantum algorithm to simulate the quantum dynamics of our proposal and show that it outperform the other proposals with less resources.

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