用于室温量子模拟的速度扫描断层成像技术

IF 8.1 1区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Physical review letters Pub Date : 2024-10-29 DOI:10.1103/physrevlett.133.183403

Jiefei Wang, Ruosong Mao, Xingqi Xu, Yunzhou Lu, Jianhao Dai, Xiao Liu, Gang-Qin Liu, Dawei Lu, Huizhu Hu, Shi-Yao Zhu, Han Cai, Da-Wei Wang

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引用次数: 0

摘要

量子模拟提供了一种利用可控平台探索奇异量子现象的模拟方法，通常需要超低温来保持量子相干性。超光度晶格（SL）已被用来模拟室温下的相干拓扑物理，但原子的热运动仍然是精确测量物理量的一个显著挑战。为了克服这一障碍，我们采用了一种速度扫描断层扫描技术来分辨不同速度原子的响应，从而在室温辐照室内实现冷原子光谱分辨率。通过比较有原子和无原子以特定速度运动时的吸收光谱，我们可以得出 SL 在各种有效静态电场下的万尼尔-斯塔克梯度，其强度与原子速度成正比。我们通过监测阶梯频移与原子速度的函数关系来提取 SL 的扎克相位，从而有效地证明了能带的拓扑缠绕。我们的研究证明了室温量子模拟的可行性，并促进了它们在量子信息处理中的应用。

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Velocity Scanning Tomography for Room-Temperature Quantum Simulation

Quantum simulation offers an analog approach for exploring exotic quantum phenomena using controllable platforms, typically necessitating ultracold temperatures to maintain the quantum coherence. Superradiance lattices (SLs) have been harnessed to simulate coherent topological physics at room temperature, but the thermal motion of atoms remains a notable challenge in accurately measuring the physical quantities. To overcome this obstacle, we implement a velocity scanning tomography technique to discern the responses of atoms with different velocities, allowing cold-atom spectroscopic resolution within room-temperature SLs. By comparing absorption spectra with and without atoms moving at specific velocities, we can derive the Wannier-Stark ladders of the SL across various effective static electric fields, their strengths being proportional to the atomic velocities. We extract the Zak phase of the SL by monitoring the ladder frequency shift as a function of the atomic velocity, effectively demonstrating the topological winding of the energy bands. Our research signifies the feasibility of room-temperature quantum simulation and facilitates their applications in quantum information processing.

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来源期刊

Physical review letters 物理-物理：综合

CiteScore

16.50

自引率

7.00%

发文量

2673

审稿时长

2.2 months

期刊介绍： Physical review letters(PRL)covers the full range of applied, fundamental, and interdisciplinary physics research topics: General physics, including statistical and quantum mechanics and quantum information Gravitation, astrophysics, and cosmology Elementary particles and fields Nuclear physics Atomic, molecular, and optical physics Nonlinear dynamics, fluid dynamics, and classical optics Plasma and beam physics Condensed matter and materials physics Polymers, soft matter, biological, climate and interdisciplinary physics, including networks