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Cavity QED in a high NA resonator

Danial Shadmany, Aishwarya Kumar, Anna Soper, Lukas Palm, Chuan Yin, Henry Ando, Bowen Li, Lavanya Taneja, Matt Jaffe, David Schuster, Jonathan Simon

2025Science Advances16 citationsDOIOpen Access PDF

Abstract

From fundamental studies of light-matter interaction to applications in quantum networking and sensing, cavity quantum electrodynamics (QED) provides a toolbox to control interactions between atoms and photons. The coherence of interactions is determined by the single-pass atomic absorption and number of photon round-trips. Reducing the cavity loss has enabled resonators supporting 1 million roundtrips but with limited material choices and increased alignment sensitivity. Here, we present a high–numerical aperture, lens-based resonator that pushes the single-atom single-photon absorption probability near its fundamental limit, reducing the mode size at the atom to order λ. This resonator provides a single-atom cooperativity of 1.6 in a cavity where the light circulates ∼10 times. We load single 87 Rb atoms into this cavity, observe strong coupling, and demonstrate cavity-enhanced atom detection with fidelity of 99.55(6)% and survival of 99.89(4)% in 130 μs. Introducing intracavity imaging systems will enable cavity arrays compatible with Rydberg atom array computing technologies, expanding the applicability of the cavity QED toolbox.

Topics & Concepts

Cavity quantum electrodynamicsPhysicsResonatorPhotonOptical cavityAtom (system on chip)Absorption (acoustics)Coupling (piping)Atomic physicsOptoelectronicsOpticsQuantumQuantum mechanicsMaterials scienceLaserOpen quantum systemMetallurgyEmbedded systemComputer scienceQuantum Information and CryptographyCold Atom Physics and Bose-Einstein CondensatesMechanical and Optical Resonators
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