TY - JOUR
T1 - Overcoming Frequency Resolution Limits Using a Solid-State Spin Quantum Sensor
AU - Cao, Qingyun
AU - Genov, Genko T.
AU - Chu, Yaoming
AU - Cai, Jianming
AU - Liu, Yu
AU - Retzker, Alex
AU - Jelezko, Fedor
N1 - Publisher Copyright:
© 2025 authors. Published by the American Physical Society.
PY - 2025/12/19
Y1 - 2025/12/19
N2 - The ability to determine precisely the separation of two frequencies is fundamental to spectroscopy, yet the resolution limit poses a critical challenge: distinguishing two incoherent signals becomes impossible when their frequencies are sufficiently close. Here, we demonstrate a simple and powerful approach, dubbed superresolution quantum sensing, which experimentally resolves two nearly identical incoherent signals using a solid-state spin quantum sensor. By carefully choosing interrogation times that satisfy the superresolution condition, we eliminate quantum projection noise, overcoming the vanishing distinguishability of signals with near-identical frequencies. This leads to improved resolution, which scales as t-2 in comparison to the standard t-1 scaling. Together with a greatly reduced classical readout noise assisted by a nuclear spin, we are able to achieve sub-kHz resolution with a signal detection time of 80 μs. Our results highlight the potential of quantum sensing to overcome conventional frequency resolution limitations, with broad implications for precision measurements.
AB - The ability to determine precisely the separation of two frequencies is fundamental to spectroscopy, yet the resolution limit poses a critical challenge: distinguishing two incoherent signals becomes impossible when their frequencies are sufficiently close. Here, we demonstrate a simple and powerful approach, dubbed superresolution quantum sensing, which experimentally resolves two nearly identical incoherent signals using a solid-state spin quantum sensor. By carefully choosing interrogation times that satisfy the superresolution condition, we eliminate quantum projection noise, overcoming the vanishing distinguishability of signals with near-identical frequencies. This leads to improved resolution, which scales as t-2 in comparison to the standard t-1 scaling. Together with a greatly reduced classical readout noise assisted by a nuclear spin, we are able to achieve sub-kHz resolution with a signal detection time of 80 μs. Our results highlight the potential of quantum sensing to overcome conventional frequency resolution limitations, with broad implications for precision measurements.
UR - https://www.scopus.com/pages/publications/105025408705
U2 - 10.1103/llfg-s4rr
DO - 10.1103/llfg-s4rr
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AN - SCOPUS:105025408705
SN - 0031-9007
VL - 135
JO - Physical Review Letters
JF - Physical Review Letters
IS - 25
M1 - 250806
ER -