光共振器アレイにより量子スーパーコンピュータの基盤技術を実証 （Light-Based Platform Sets the Stage for Quantum Supercomputers）

2026-01-28 スタンフォード大学

Various optics, including lenses and mirrors, as well as other test equipment which are used for directing and measuring the light collected from atoms in the cavity array microscope. | LiPo Ching for Stanford University

＜関連情報＞

• https://news.stanford.edu/stories/2026/01/optical-cavity-array-light-based-platform-quantum-supercomputers
• https://www.nature.com/articles/s41586-025-10035-9

並列単一原子インターフェース用キャビティアレイ顕微鏡 A cavity-array microscope for parallel single-atom interfacing

Adam L. Shaw,Anna Soper,Danial Shadmany,Aishwarya Kumar,Lukas Palm,Da-Yeon Koh,Vassilios Kaxiras,Lavanya Taneja,Matt Jaffe,David I. Schuster & Jonathan Simon
Nature  Published:28 January 2026
DOI:https://doi.org/10.1038/s41586-025-10035-9

Abstract

Neutral-atom arrays and optical cavity quantum electrodynamics systems have developed in parallel as central pillars of modern experimental quantum science^1,2,3. Although each platform has shown exceptional capabilities—such as high-fidelity quantum logic^4,5,6,7 in atom arrays and strong light–matter coupling in cavities^8,9,10—their combination holds promise for realizing fast and non-destructive atom measurement¹¹, building large-scale quantum networks^{12,13,14,15,16,17} and engineering hybrid atom–photon Hamiltonians^18,19,20. However, so far, experiments integrating the two platforms have been limited to spatially interfacing the entire atom array with one global cavity mode^{21,22,23,24,25,26}, a configuration that constrains addressability, parallelism and scalability. Here we introduce the cavity-array microscope, an experimental platform where each individual atom is strongly coupled to its own individual cavity across a two-dimensional array of over 40 modes. Our approach requires no nanophotonic elements^26,27, and instead uses a free-space cavity geometry with intra-cavity lenses^28,29 to realize above-unity peak cooperativity with micrometre-scale mode waists and spacings, compatible with typical atom-array length scales while keeping atoms far from dielectric surfaces. We achieve homogeneous atom–cavity coupling and show fast, non-destructive, parallel readout on millisecond timescales, including through a fibre array as a proof of principle for networking applications³⁰. As an outlook, we realize a next-generation iteration of the platform with over 500 cavities and a nearly 10-fold improvement in finesse. Our work unlocks the regime of many-cavity quantum electrodynamics and opens an unexplored frontier of large-scale quantum networking with atom arrays.