芯片级平台的激光冷却

arXiv: Atomic Physics Pub Date : 2020-05-12 DOI:10.1063/5.0014658

J. McGilligan, J. McGilligan, K. Moore, A. Dellis, A. Dellis, G. Martinez, G. Martinez, E. Clercq, P. Griffin, A. Arnold, E. Riis, R. Boudot, R. Boudot, J. Kitching

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引用次数: 29

摘要

芯片级原子器件围绕微制造碱蒸汽电池构建，是紧凑型计量和原子传感器的前沿。我们展示了一种微型制造的蒸汽电池，它被主动泵送到超高真空(UHV)来实现激光冷却。将光栅磁光阱(GMOT)与4 mm厚的硅/玻璃真空电池结合在一起，以证明完全小型化激光冷却平台的可行性。利用铷的两步光激发过程克服了表面散射对GMOT成像的限制。微型制造的特高压电池具有明确的小型化和形状可定制性，为未来的紧凑型冷原子传感器提供了一个有前途的平台。

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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Laser cooling in a chip-scale platform

Chip-scale atomic devices built around micro-fabricated alkali vapor cells are at the forefront of compact metrology and atomic sensors. We demonstrate a micro-fabricated vapor cell that is actively-pumped to ultra-high-vacuum (UHV) to achieve laser cooling. A grating magneto optical trap (GMOT) is incorporated with the 4 mm-thick Si/glass vacuum cell to demonstrate the feasibility of a fully-miniaturized laser cooling platform. A two-step optical excitation process in rubidium is used to overcome surface-scatter limitations to the GMOT imaging. The unambiguous miniaturization and form-customizability made available with micro-fabricated UHV cells provide a promising platform for future compact cold-atom sensors.

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arXiv: Atomic Physics

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