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Main Authors: Yuan, Ji-Bing, Tang, Zhi-Min, Song, Ya-Ju, Tang, Shi-Qing, Peng, Zhao-Hui, Wang, Xin-Wen, Kuang, Le-Man
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2310.12445
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author Yuan, Ji-Bing
Tang, Zhi-Min
Song, Ya-Ju
Tang, Shi-Qing
Peng, Zhao-Hui
Wang, Xin-Wen
Kuang, Le-Man
author_facet Yuan, Ji-Bing
Tang, Zhi-Min
Song, Ya-Ju
Tang, Shi-Qing
Peng, Zhao-Hui
Wang, Xin-Wen
Kuang, Le-Man
contents We investigate the utilization of a single generalized dephasing qubit for sensing a quantum reservoir, where the antisymmetric coupling between the qubit and its reservoir is broken. It is found that in addition to the decay factor encoding channel, the antisymmetric coupling breaking gives rise to another phase factor encoding channel. We introduce an optimal measurement for the generalized dephasing qubit which enables the practical measurement precision to reach the theoretical ultimate precision quantified by the quantum signal-to-noise ratio (QSNR). As an example, the generalized dephasing qubit is employed to estimate the $s$-wave scattering length of an atomic Bose-Einstein condensate. It is found that the phase-induced QSNR caused by the antisymmetric coupling breaking is at least two orders of magnitude higher than the decay-induced QSNR at the millisecond timescale and the optimal relative error can achieve a scaling $\propto 1/t$ with $t$ being the encoding time in long-term encoding. Our work opens a way for supersensitive sensing of quantum reservoirs.
format Preprint
id arxiv_https___arxiv_org_abs_2310_12445
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Antisymmetry-breaking-coupling-enhanced sensing of quantum reservoirs
Yuan, Ji-Bing
Tang, Zhi-Min
Song, Ya-Ju
Tang, Shi-Qing
Peng, Zhao-Hui
Wang, Xin-Wen
Kuang, Le-Man
Quantum Physics
We investigate the utilization of a single generalized dephasing qubit for sensing a quantum reservoir, where the antisymmetric coupling between the qubit and its reservoir is broken. It is found that in addition to the decay factor encoding channel, the antisymmetric coupling breaking gives rise to another phase factor encoding channel. We introduce an optimal measurement for the generalized dephasing qubit which enables the practical measurement precision to reach the theoretical ultimate precision quantified by the quantum signal-to-noise ratio (QSNR). As an example, the generalized dephasing qubit is employed to estimate the $s$-wave scattering length of an atomic Bose-Einstein condensate. It is found that the phase-induced QSNR caused by the antisymmetric coupling breaking is at least two orders of magnitude higher than the decay-induced QSNR at the millisecond timescale and the optimal relative error can achieve a scaling $\propto 1/t$ with $t$ being the encoding time in long-term encoding. Our work opens a way for supersensitive sensing of quantum reservoirs.
title Antisymmetry-breaking-coupling-enhanced sensing of quantum reservoirs
topic Quantum Physics
url https://arxiv.org/abs/2310.12445