Electron Paramagnetic Resonance signature of point defects in neutron irradiated hexagonal Boron Nitride

TL;DR

This study identifies and characterizes neutron irradiation-induced point defects in hexagonal boron nitride using electron paramagnetic resonance, revealing their optical properties and thermal stability relevant for quantum photonics.

Contribution

The paper reports the first EPR characterization of neutron-induced point defects in h-BN, linking specific defect structures to optical features and thermal behavior.

Findings

Defects are linked to nitrogen vacancies with specific spin properties.

Pink coloration and optical bands are associated with these defects.

Thermal treatments alter defect signals and optical properties.

Abstract

Hexagonal boron nitride (h-BN) is an attractive van der Waals material for studying fluorescent defects due to its large bandgap. In this work, we demonstrate enhanced pink color due to neutron irradiation and perform electron paramagnetic resonance (EPR) measurements. The new point defects are tentatively assigned to doubly- occupied nitrogen vacancies with (S = 1) and a zero-field splitting (D = 1.2 GHz). These defects are associated with a broad visible optical absorption band and near infrared photoluminescence band centered at ~ 490 nm and 820 nm, respectively. The EPR signal intensities are strongly affected by thermal treatments in temperature range between 600 to 800{\deg}C, where also the irradiation - induced pink color is lost. Our results are important for understanding of point defects in h-BN and their deployment for quantum and integrated photonic applications.