Microsecond-scale high-survival and number-resolved detection of ytterbium atom arrays

TL;DR

This paper presents a rapid, high-fidelity method for detecting individual ytterbium atoms in optical tweezers without active cooling, enabling repeated measurements, number resolution, and applications in quantum simulation and metrology.

Contribution

It introduces a novel fast, low-loss imaging technique for ytterbium atoms that does not require active cooling, allowing multiple consecutive detections and number-resolved imaging in dense arrays.

Findings

Single-atom discrimination fidelity above 99.9%

Single-shot survival probability above 99.5%

Tens of consecutive detections with constant atom retention

Abstract

Scalable atom-based quantum platforms for simulation, computing, and metrology require fast high-fidelity, low-loss imaging of individual atoms. Standard fluorescence detection methods rely on continuous cooling, limiting the detection range to one atom and imposing long imaging times that constrain the experimental cycle and mid-circuit conditional operations. Here, we demonstrate fast and low-loss single-atom imaging in optical tweezers without active cooling, enabled by the favorable properties of ytterbium. Collecting fluorescence over microsecond timescales, we reach single-atom discrimination fidelities above 99.9% and single-shot survival probabilities above 99.5%. Through interleaved recooling pulses, as short as a few hundred microseconds for atoms in magic traps, we perform tens of consecutive detections with constant atom-retention probability per image - an essential step toward fast atom re-use in tweezer-based processors and clocks. Our scheme does not induce parity projection in multiply-occupied traps, enabling number-resolved single-shot detection of several atoms per site. This allows us to study the near-deterministic preparation of single atoms in tweezers driven by blue-detuned light-assisted collisions. Moreover, the near-diffraction-limited spatial resolution of our low-loss imaging enables number-resolved microscopy in dense arrays, opening the way to direct site-occupancy readout in optical lattices for density fluctuation and correlation measurements in quantum simulators.