利用强化学习制备量子挤压态的策略

IF 2.2 4区 物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY Annalen der Physik Pub Date : 2024-06-17 DOI:10.1002/andp.202400056
Xiaolong Zhao, Yiming Zhao, Ming Li, Tingting Li, Qian Liu, Shuai Guo, Xuexi Yi
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摘要

本文提出了一种利用强化学习来设计控制场以生成非经典状态的方案。该方案的应用实例是为一个开放式集体自旋模型准备自旋挤压状态,在该模型中设计了一个线性控制场来控制动力学。强化学习代理决定控制脉冲的时间序列,在以耗散和去相为特征的环境中从相干自旋状态开始。与恒定控制方案相比,这种方法提供了各种保持集体自旋挤压和纠缠的控制序列。据观察,更密集地应用控制脉冲可提高结果的性能。不过,通过增加控制动作,性能也有小幅提升。所提出的策略对更大的系统更有效。水库的热激励对控制结果不利。根据与其他控制建议的比较,提出了实施该控制建议的可行实验。还讨论了对连续控制问题和另一种量子系统的扩展。此外,还强调了强化学习模块的可替代性。这项研究为其在其他量子系统中的应用铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A Strategy for Preparing Quantum Squeezed States Using Reinforcement Learning

A scheme leveraging reinforcement learning to engineer control fields for generating non-classical states is proposed. It is exemplified by the application to prepare spin-squeezed states for an open collective spin model where a linear control field is designed to govern the dynamics. The reinforcement learning agent determines the temporal sequence of control pulses, commencing from a coherent spin state in an environment characterized by dissipation and dephasing. Compared to the constant control scenario, this approach provides various control sequences maintaining collective spin squeezing and entanglement. It is observed that denser application of the control pulses enhances the performance of the outcomes. However, there is a minor enhancement in the performance by adding control actions. The proposed strategy demonstrates increased effectiveness for larger systems. Thermal excitations of the reservoir are detrimental to the control outcomes. Feasible experiments are suggested to implement this control proposal based on the comparison with the others. The extensions to continuous control problems and another quantum system are discussed. The replaceability of the reinforcement learning module is also emphasized. This research paves the way for its application in manipulating other quantum systems.

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来源期刊
Annalen der Physik
Annalen der Physik 物理-物理:综合
CiteScore
4.50
自引率
8.30%
发文量
202
审稿时长
3 months
期刊介绍: Annalen der Physik (AdP) is one of the world''s most renowned physics journals with an over 225 years'' tradition of excellence. Based on the fame of seminal papers by Einstein, Planck and many others, the journal is now tuned towards today''s most exciting findings including the annual Nobel Lectures. AdP comprises all areas of physics, with particular emphasis on important, significant and highly relevant results. Topics range from fundamental research to forefront applications including dynamic and interdisciplinary fields. The journal covers theory, simulation and experiment, e.g., but not exclusively, in condensed matter, quantum physics, photonics, materials physics, high energy, gravitation and astrophysics. It welcomes Rapid Research Letters, Original Papers, Review and Feature Articles.
期刊最新文献
(Ann. Phys. 11/2024) (Ann. Phys. 11/2024) Masthead: Ann. Phys. 11/2024 (Ann. Phys. 10/2024) Masthead: Ann. Phys. 10/2024
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