English

Coupling light to an atomic tweezer array in a cavity

Quantum Physics 2023-12-19 v1

Abstract

We consider the coupling of light, via an optical cavity, to two-dimensional atomic arrays whose lattice spacing exceeds the wavelength of the light. Such 'superwavelength' spacing is typical of optical tweezer arrays. While subwavelength arrays exhibit strong atom-photon coupling, characterized by high optical reflectivity in free space, the coupling efficiency of superwavelength arrays is reduced due to collective scattering losses to high diffraction orders. We show that a moderate-finesse cavity overcomes these losses. As the scattering losses peak at certain discrete values of the lattice spacing, the spacing can be optimized to achieve efficient atom-photon coupling in the cavity. Our cavity-QED theory properly accounts for collective dipolar interactions mediated by the lossy, non-cavity-confined photon modes and for finite-size effects of both the array and the light field. These findings pave the way to harnessing the versatility of tweezer arrays for efficient atom-photon interfaces in applications of quantum computing, networking, and nonlinear optics.

Keywords

Cite

@article{arxiv.2312.11104,
  title  = {Coupling light to an atomic tweezer array in a cavity},
  author = {Yakov Solomons and Inbar Shani and Ofer Firstenberg and Nir Davidson and Ephraim Shahmoon},
  journal= {arXiv preprint arXiv:2312.11104},
  year   = {2023}
}

Comments

4 figures

R2 v1 2026-06-28T13:54:29.519Z