TY - JOUR
T1 - Dark matter search with a resonantly-coupled hybrid spin system
AU - Wei, Kai
AU - Xu, Zitong
AU - He, Yuxuan
AU - Ma, Xiaolin
AU - Heng, Xing
AU - Huang, Xiaofei
AU - Quan, Wei
AU - Ji, Wei
AU - Liu, Jia
AU - Wang, Xiao Ping
AU - Budker, Dmitry
AU - Fang, Jiancheng
N1 - Publisher Copyright:
© 2025 The Author(s). Published by IOP Publishing Ltd.
PY - 2025/5/1
Y1 - 2025/5/1
N2 - Recent advances in tabletop quantum sensor technology have enabled searches for nongravitational interactions of dark matter (DM). Traditional axion DM experiments rely on sharp resonance, resulting in extensive scanning time to cover a wide mass range. In this work, we present a broadband approach in an alkali- 21 Ne spin system. We identify two distinct hybrid spin-coupled regimes: a self-compensation regime at low frequencies and a hybrid spin resonance regime at higher frequencies. By utilizing these two distinct regimes, we significantly enhance the bandwidth of 21 Ne nuclear spin compared to conventional nuclear magnetic resonance, while maintaining competitive sensitivity. We present a comprehensive broadband search for axion-like DM, covering 5 orders of magnitude of Compton frequencies range within [ 10 − 2 , 10 3 ] Hz. We set new constraints on the axion DM interactions with neutrons and protons, accounting for the effects of DM stochasticity. For the axion-neutron coupling, our results reach a low value of | g ann | ⩽ 3 × 10 − 10 in the frequency range [ 2 × 10 − 2 , 4 ] Hz surpassing astrophysical limits and providing the strongest laboratory constraints in the [ 10 , 100 ] Hz range. For the axion-proton coupling, we offer the best terrestrial constraints for the frequency ranges [ 2 × 10 − 2 , 5 ] Hz and [ 16 , 7 × 10 2 ] Hz.
AB - Recent advances in tabletop quantum sensor technology have enabled searches for nongravitational interactions of dark matter (DM). Traditional axion DM experiments rely on sharp resonance, resulting in extensive scanning time to cover a wide mass range. In this work, we present a broadband approach in an alkali- 21 Ne spin system. We identify two distinct hybrid spin-coupled regimes: a self-compensation regime at low frequencies and a hybrid spin resonance regime at higher frequencies. By utilizing these two distinct regimes, we significantly enhance the bandwidth of 21 Ne nuclear spin compared to conventional nuclear magnetic resonance, while maintaining competitive sensitivity. We present a comprehensive broadband search for axion-like DM, covering 5 orders of magnitude of Compton frequencies range within [ 10 − 2 , 10 3 ] Hz. We set new constraints on the axion DM interactions with neutrons and protons, accounting for the effects of DM stochasticity. For the axion-neutron coupling, our results reach a low value of | g ann | ⩽ 3 × 10 − 10 in the frequency range [ 2 × 10 − 2 , 4 ] Hz surpassing astrophysical limits and providing the strongest laboratory constraints in the [ 10 , 100 ] Hz range. For the axion-proton coupling, we offer the best terrestrial constraints for the frequency ranges [ 2 × 10 − 2 , 5 ] Hz and [ 16 , 7 × 10 2 ] Hz.
KW - axion
KW - axion-like-particles
KW - axion-nucleon interactions
KW - comagnetometer
KW - dark matter
UR - https://www.scopus.com/pages/publications/105003246736
U2 - 10.1088/1361-6633/adca52
DO - 10.1088/1361-6633/adca52
M3 - 文章
C2 - 40199331
AN - SCOPUS:105003246736
SN - 0034-4885
VL - 88
JO - Reports on Progress in Physics
JF - Reports on Progress in Physics
IS - 5
M1 - 057801
ER -