Utilizing encoding time as a resource to enhance quantum sensing by probe qubit dephasing
Abstract
We examine a system in which an impurity qubit is immersed in a quasi-two-dimensional dipolar Bose-Einstein condensate whose collective excitations act as a depasing reservoir for the qubit. The relative dipole-dipole interaction strength is estimated by the probe qubit dephasing. The ultimate precision of this estimation is quantified by the quantum Fisher information, which can be obtained by means of measuring quantum coherence of the probe qubit. Our findings indicate that, in the interval where roton excitations appear, the quantum Fisher information oscillates periodically with the encoding time , and the amplitude of these oscillations increases alongside the extension of . Moreover, we analytically determine that the envelope curve formed by the local maximum points satisfies the functional relationship during long-term encoding scenarios, where , , are positive numbers. It is also revealed that the highly non-Markovian effects caused by the roton softening of the excitation spectrum allow long encoding time to serve as a resource for enhancing sensing precision. Our work provides a new pathway for enhancing the sensing precision of dephasing qubits.
Cite
@article{arxiv.2411.19438,
title = {Utilizing encoding time as a resource to enhance quantum sensing by probe qubit dephasing},
author = {Ji-Bing Yuan and Hai-Fei Liu and Ya-Ju Song and Shi-Qing Tang and Xin-Wen Wang and Le-Man Kuang},
journal= {arXiv preprint arXiv:2411.19438},
year = {2024}
}
Comments
9 pages, 8 figures