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Spin defects in hBN as promising temperature, pressure and magnetic field quantum sensors

Physics

Spin defects in hBN as promising temperature, pressure and magnetic field quantum sensors

A. Gottscholl, M. Diez, et al.

This groundbreaking research by authors including Andreas Gottscholl and Matthias Diez reveals how negatively charged boron vacancies in hexagonal boron nitride can serve as atomic-scale sensors for measuring temperature, magnetic fields, and pressure. The findings highlight the impressive sensitivity of these intrinsic sensors in 2D material heterostructures.

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~3 min • Beginner • English
Abstract
Spin defects in solid-state materials are strong candidate systems for quantum information technology and sensing applications. Here we explore in details the recently discovered negatively charged boron vacancies (V_B^−) in hexagonal boron nitride (hBN) and demonstrate their use as atomic scale sensors for temperature, magnetic fields and externally applied pressure. These applications are possible due to the high-spin triplet ground state and bright spin-dependent photoluminescence of the V_B^−. Specifically, we find that the frequency shift in optically detected magnetic resonance measurements is not only sensitive to static magnetic fields, but also to temperature and pressure changes which we relate to crystal lattice parameters. We show that spin-rich hBN films are potentially applicable as intrinsic sensors in heterostructures made of functionalized 2D materials.
Publisher
Nature Communications
Published On
Jul 22, 2021
Authors
Andreas Gottscholl, Matthias Diez, Victor Soltamov, Christian Kasper, Dominik Krauße, Andreas Sperlich, Mehran Kianinia, Carlo Bradac, Igor Aharonovich, Vladimir Dyakonov
Tags
boron vacancies
hexagonal boron nitride
sensors
temperature
magnetic fields
pressure
photoluminescence

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