English

Velocity Scanning Tomography for Room-Temperature Quantum Simulation

Quantum Physics 2024-10-30 v1 Quantum Gases Optics

Abstract

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 invent and validate 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.

Keywords

Cite

@article{arxiv.2406.02494,
  title  = {Velocity Scanning Tomography for Room-Temperature Quantum Simulation},
  author = {Jiefei Wang and Ruosong Mao and Xingqi Xu and Yunzhou Lu and Jianhao Dai and Xiao Liu and Gang-Qin Liu and Dawei Lu and Huizhu Hu and Shi-Yao Zhu and Han Cai and Da-Wei Wang},
  journal= {arXiv preprint arXiv:2406.02494},
  year   = {2024}
}

Comments

6 pages, 4 figures

R2 v1 2026-06-28T16:53:14.815Z