Nonlinear time-reversal interferometry with arbitrary quadratic collective-spin interaction
Abstract
Atomic nonlinear interferometry has wide applications in quantum metrology and quantum information science. Here we propose a nonlinear time-reversal interferometry scheme with high robustness and metrological gain based on the spin squeezing generated by arbitrary quadratic collective-spin interaction, which could be described by the Lipkin-Meshkov-Glick (LMG) model. We optimize the squeezing process, encoding process, and anti-squeezing process, finding that the two particular cases of the LMG model, one-axis twisting and two-axis twisting outperform in robustness and precision, respectively. Moreover, we propose a Floquet driving method to realize equivalent time reverse in the atomic system, which leads to high performance in precision, robustness, and operability. Our study sets a benchmark in achieving high precision and robustness in atomic nonlinear interferometry.
Cite
@article{arxiv.2308.04042,
title = {Nonlinear time-reversal interferometry with arbitrary quadratic collective-spin interaction},
author = {Zhiyao Hu and Qixian Li and Xuanchen Zhang and He-bin Zhang and Long-Gang Huang and Yong-Chun Liu},
journal= {arXiv preprint arXiv:2308.04042},
year = {2023}
}
Comments
10 pages,8figures