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Quantum Sensing of Broadband Spin Dynamics and Magnon Transport in Antiferromagnets

Authors :
Melendez, Alex Lee
Das, Shekhar
Rodriguez, Francisco Ayala
Kao, I-Hsuan
Liu, Wenhao
Williams, Archibald J.
Lv, Bing
Goldberger, Joshua
Chatterjee, Shubhayu
Singh, Simranjeet
Hammel, P. Chris
Publication Year :
2024

Abstract

Optical detection of magnetic resonance using quantum spin sensors (QSS) provides a spatially local and sensitive technique to probe spin dynamics in magnets. However, its utility as a probe of antiferromagnetic resonance (AFMR), wherein the characteristic resonant frequencies substantially exceed the QSS probing frequency, remains an open question. Here, using the nitrogen-vacancy center in diamond as a QSS, we report the first experimental demonstration of optically detected AFMR in layered van der Waals antiferromagnets up to frequencies of 24 GHz, significantly higher than the sensor's spin resonance frequency of 2.87 GHz. To achieve this, we leverage the enhancement of the QSS spin relaxation rate due to low-frequency magnetic field fluctuations that arise from collective late-time dynamics of finite-wavevector magnons excited by the driven uniform AFMR mode. Using optically detected AFMR, we first characterize the temperature and magnetic field dependence on the AFMR modes, which shed light on the intrinsic exchange fields and magnetic anisotropies. Second, we exploit the highly localized sensitivity of the QSS to demonstrate efficient magnon transport over tens of micrometers. Finally, we find that optical detection efficiency in fact increases with increasing frequency, enabling broadband detection of magnetization dynamics. Our work showcases the dual capabilities of QSS as detectors of both high frequency magnetization dynamics and magnon transport, paving the way for understanding and controlling magnetism in Neel states in antiferromagnets.

Details

Database :
arXiv
Publication Type :
Report
Accession number :
edsarx.2410.23421
Document Type :
Working Paper