微波驱动的耗散雷德堡气体中出现的次谐波

Zong-Kai Liu, Kong-Hao Sun, Albert Cabot, Federico Carollo, Jun Zhang, Zheng-Yuan Zhang, Li-Hua Zhang, Bang Liu, Tian-Yu Han, Qing Li, Yu Ma, Han-Chao Chen, Igor Lesanovsky, Dong-Sheng Ding, Bao-Sen Shi
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引用次数: 0

摘要

接近相变的量子多体系统会对外部施加的扰动做出集体反应。我们在激光驱动的耗散雷德贝格气体中探索了这一现象,该气体被调整为双稳态。这里共存着两个蜕变相,分别具有低密度和高密度的 Rydberg 原子。我们在现场监测到的随之而来的集体动力学特征是这两个宏观上截然不同的多体相之间的随机集体跃迁。我们的研究表明,这些跃迁的统计量可以用双音微波场来控制。特别是,我们发现跃迁时间的分布会出现与相对微波失谐的次谐波相对应的峰值。我们的研究展示了对耗散量子多体系统集体统计特性的控制,而无需微调或超低温。这种稳健的多体现象可能会在传感技术中得到应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Emergence of subharmonics in a microwave driven dissipative Rydberg gas

Emergence of subharmonics in a microwave driven dissipative Rydberg gas
Quantum many-body systems near phase transitions respond collectively to externally applied perturbations. We explore this phenomenon in a laser-driven dissipative Rydberg gas that is tuned to a bistable regime. Here two metastable phases coexist, which feature a low and high density of Rydberg atoms, respectively. The ensuing collective dynamics, which we monitor in situ, is characterized by stochastic collective jumps between these two macroscopically distinct many-body phases. We show that the statistics of these jumps can be controlled using a dual-tone microwave field. In particular, we find that the distribution of jump times develops peaks corresponding to subharmonics of the relative microwave detuning. Our study demonstrates the control of collective statistical properties of dissipative quantum many-body systems without the necessity of fine-tuning or of ultracold temperatures. Such robust many-body phenomena may find technological applications in sensing.
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CiteScore
8.60
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