Super-resolving frequency measurement with mode-selective quantum memory

Journal article

Abstract High-precision optical frequency measurement underpins modern science and technology, yet conventional spectroscopic techniques struggle to resolve sublinewidth spectral features. Here we introduce a platform for super-resolved frequency estimation based on a mode-selective atomic Raman quantum memory implemented in warm caesium vapour. By precisely engineering the light–matter interaction, the memory coherently stores the optimal temporal mode with high fidelity and retrieves it on demand, achieving mode crosstalk as low as 0.34%. To estimate the separation between two spectral lines, we experimentally measure the mean squared error of the frequency estimate, reaching a sensitivity of 1/20 of the linewidth and a (34 ± 4)-fold enhancement in precision over direct intensity measurements. This enhanced frequency resolution, combined with on-demand storage, retrieval and mode-conversion capabilities, establishes a pathway towards multifunctional memory-based time–frequency sensors and their integration within quantum networks.

Authors: Zhang, S; Zhang, A; Maillette de Buy Wenniger, I; Burdekin, PM; Sagona-Stophel, S

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: Nature Research
• Journal: Nature Sensors
• Publication date: 2026-05-15
• DOI: 10.1038/s44460-026-00073-9
• EISSN: 3059-4499
• ISSN: 3059-4499
• Language: English
• Keywords: Quantum sensor; Sensitivity (control systems); Quantum metrology; Time delay and integration; Laser linewidth; Quantum memory; Quantum; Measure (data warehouse); Crosstalk; Frequency modulation