English

Geometrically asymmetric optical cavity for strong atom-photon coupling

Atomic Physics 2019-02-07 v3 Instrumentation and Detectors Quantum Physics

Abstract

Optical cavities are widely used to enhance the interaction between atoms and light. Typical designs using a geometrically symmetric structure in the near-concentric regime face a tradeoff between mechanical stability and high single-atom cooperativity. To overcome this limitation, we design and implement a geometrically asymmetric standing-wave cavity. This structure, with mirrors of very different radii of curvature, allows strong atom-light coupling while exhibiting good stability against misalignment. We observe effective cooperativities ranging from ηeff=10\eta_{\rm eff}=10 to ηeff=0.2\eta_{\rm eff}=0.2 by shifting the location of the atoms in the cavity mode. By loading 171^{171}Yb atoms directly from a mirror magneto-optical trap into a one-dimensional optical lattice along the cavity mode, we produce atomic ensembles with collective cooperativities up to Nη=2×104N\eta=2\times 10^4. This system opens a way to preparing spin squeezing for an optical lattice clock and to accessing a range of nonclassical collective states.

Keywords

Cite

@article{arxiv.1811.08093,
  title  = {Geometrically asymmetric optical cavity for strong atom-photon coupling},
  author = {Akio Kawasaki and Boris Braverman and Edwin Pedrozo-Peñafiel and Chi Shu and Simone Colombo and Zeyang Li and Özge Özel and Wenlan Chen and Leonardo Salvi and André Heinz and David Levonian and Daisuke Akamatsu and Yanhong Xiao and Vladan Vuletić},
  journal= {arXiv preprint arXiv:1811.08093},
  year   = {2019}
}

Comments

8 pages, 7 figures, published version

R2 v1 2026-06-23T05:21:44.427Z