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Free-space quantum interface of a single atomic tweezer array with light

Quantum Physics 2025-10-28 v1

Abstract

We present a practical approach for interfacing light with a two-dimensional atomic tweezer array. Typical paraxial fields are poorly matched to the array's multi-diffraction-order radiation pattern, thus severely limiting the interface coupling efficiency. Instead, we propose to design a field mode that naturally couples to the array: it consists of a unique superposition of multiple beams corresponding to the array's diffraction orders. This composite mode can be generated from a single Gaussian beam using standard free-space optics, including spatial light modulators and a single objective lens. For a triangular array with lattice spacing about twice the wavelength, all diffraction angles remain below 35 degrees, making the scheme compatible with standard objectives of numerical aperture NA <= 0.7. Our analytical theory and scattering simulations reveal that the interface efficiency r0 for quantum information tasks scales favorably with the array atom number N: reaching >0.99 (>0.9999) for N = 149 (N approximately 1000) and scaling as 1 - r0 scales as 1/N for large N. The scheme is robust to optical imperfections and atomic-position errors, offering a viable path for quantum light-matter applications and state readout in current tweezer-array platforms.

Keywords

Cite

@article{arxiv.2510.23398,
  title  = {Free-space quantum interface of a single atomic tweezer array with light},
  author = {Yakov Solomons and Roni Ben-Maimon and Arpit Behera and Ofer Firstenberg and Nir Davidson and Ephraim Shahmoon},
  journal= {arXiv preprint arXiv:2510.23398},
  year   = {2025}
}
R2 v1 2026-07-01T07:07:48.331Z