Dynamical topological phase transition in cold Rydberg quantum gases

arXiv - PHYS - Quantum Physics Pub Date : 2024-09-17 DOI:arxiv-2409.11035

Jun Zhang, Ya-Jun Wang, Bang Liu, Li-Hua Zhang, Zheng-Yuan Zhang, Shi-Yao Shao, Qing Li, Han-Chao Chen, Yu Ma, Tian-Yu Han, Qi-Feng Wang, Jia-Dou Nan, Yi-Ming Yin, Dong-Yang Zhu, Bao-Sen Shi, Dong-Sheng Ding

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Abstract

Study of phase transitions provide insights into how a many-body system behaves under different conditions, enabling us to understand the symmetry breaking, critical phenomena, and topological properties. Strong long-range interactions in highly excited Rydberg atoms create a versatile platform for exploring exotic emergent topological phases. Here, we report the experimental observation of dynamical topological phase transitions in cold Rydberg atomic gases under a microwave field driving. By measuring the system transmission curves while varying the probe intensity, we observe complex hysteresis trajectories characterized by distinct winding numbers as they cross the critical point. At the transition state, where the winding number flips, the topology of these hysteresis trajectories evolves into more non-trivial structures. The topological trajectories are shown to be robust against noise, confirming their rigidity in dynamic conditions. These findings contribute to the insights of emergence of complex dynamical topological phases in many-body systems.

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冷雷德堡量子气体中的动态拓扑相变

对相变的研究能让我们深入了解多体系统在不同条件下的表现，使我们能够理解对称性破坏、临界现象和拓扑特性。高度激发的雷德贝格原子中的强长程相互作用为探索奇异的新兴拓扑相提供了一个多功能平台。在这里，我们报告了在微波场驱动下对冷雷德贝格原子气体中动态拓扑相变的实验观测。通过在改变探针强度的同时测量系统的传输曲线，我们观察到了复杂的滞后轨迹，这些轨迹在跨越临界点时具有不同的绕组数。在绕组数翻转的过渡状态，这些滞后轨迹的拓扑结构演变成更多的非三维结构。拓扑轨迹对噪声具有鲁棒性，证实了它们在动态条件下的刚性。这些发现有助于深入了解多体系统中复杂动态拓扑阶段的出现。

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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arXiv - PHYS - Quantum Physics

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