# Spin-resolved Visible Optical Spectra and Electronic Characteristics of   Defect-mediated Hexagonal Boron Nitride Monolayer

**Authors:** Sheng Yu, Bagher Tabibi, Qiliang Li, Felix Jaetae Seo

arXiv: 1908.03981 · 2019-12-13

## TL;DR

This study investigates the optical spectra and electronic properties of defect-laden hexagonal boron nitride monolayers, revealing defect-specific spin-resolved features and high conductivity related to various atomic vacancies and substitutions.

## Contribution

It provides a detailed analysis of how different atomic defects influence the optical and electronic properties of hBN monolayers, highlighting spin-resolved characteristics and charge effects.

## Key findings

- Defects induce spin-resolved optical and electronic features.
- Certain defects lead to high electronic conductivity.
- Positively charged defects dominate longer spectral regions.

## Abstract

The defect-mediated hexagonal boron nitride (hBN) supercell display the visible optical spectra and electronic characteristics. The defects in the hBN supercell include the atomic vacancy, antisite, antisite vacancy, and substitution of a foreign atom for boron or nitrogen. The hBN supercell with VB, CB, and NB-VN has the high electron density of states across the Fermi level which indicates the high conductive electronic characteristics. The hBN with defects including atomic vacancy, antisite vacancy, and substitution of a foreign atom for boron or nitride exhibit the distinct spin-resolved optical and electronics characteristics, while the defects of boron and nitrogen antisite do not display the spin-resolved optical characteristics. The hBN with positively charged defects has a dominant optical and electronic characteristics at the longer spectral region.

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Source: https://tomesphere.com/paper/1908.03981