Single-electron spin resonance detection by microwave photon counting

Wang, Z.; Balembois, L.; Rančić, M.; Billaud, E.; Dantec, M. Le; Ferrier, A.; Goldner, P.; Bertaina, S.; Chanelière, T.; Esteve, D.; Vion, D.; Bertet, P.; Flurin, E.

Single-electron spin resonance detection by microwave photon counting

Z. Wang, L. Balembois, M. Rančić, E. Billaud, M. Le Dantec, A. Ferrier, P. Goldner, S. Bertaina, T. Chanelière, D. Esteve, D. Vion, P. Bertet and E. Flurin ()
Additional contact information
Z. Wang: SPEC
L. Balembois: SPEC
M. Rančić: SPEC
E. Billaud: SPEC
M. Le Dantec: SPEC
A. Ferrier: Institut de Recherche de Chimie Paris
P. Goldner: Institut de Recherche de Chimie Paris
S. Bertaina: Institut Matériaux Microélectronique et Nanosciences de Provence
T. Chanelière: Institut Néel
D. Esteve: SPEC
D. Vion: SPEC
P. Bertet: SPEC
E. Flurin: SPEC

Nature, 2023, vol. 619, issue 7969, 276-281

Abstract: Abstract Electron spin resonance spectroscopy is the method of choice for characterizing paramagnetic impurities, with applications ranging from chemistry to quantum computing1,2, but it gives access only to ensemble-averaged quantities owing to its limited signal-to-noise ratio. Single-electron spin sensitivity has, however, been reached using spin-dependent photoluminescence3–5, transport measurements6–9 and scanning-probe techniques10–12. These methods are system-specific or sensitive only in a small detection volume13,14, so that practical single-spin detection remains an open challenge. Here, we demonstrate single-electron magnetic resonance by spin fluorescence detection15, using a microwave photon counter at millikelvin temperatures16. We detect individual paramagnetic erbium ions in a scheelite crystal coupled to a high-quality-factor planar superconducting resonator to enhance their radiative decay rate17, with a signal-to-noise ratio of 1.9 in one second integration time. The fluorescence signal shows anti-bunching, proving that it comes from individual emitters. Coherence times up to 3 ms are measured, limited by the spin radiative lifetime. The method has the potential to be applied to arbitrary paramagnetic species with long enough non-radiative relaxation times, and allows single-spin detection in a volume as large as the resonator magnetic mode volume (approximately 10 μm3 in the present experiment), orders of magnitude larger than other single-spin detection techniques. As such, it may find applications in magnetic resonance and quantum computing.

Date: 2023
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DOI: 10.1038/s41586-023-06097-2

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