# $\mathrm{BaAs_3}$: A narrow gap 2D semiconductor with vacancy-induced   semiconductor-metal transition

**Authors:** Ping Tang, Jun-Hui Yuan, Ya-Qian Song, Ming Xu, Kan-Hao Xue,, Xiang-Shui Miao

arXiv: 1904.08742 · 2024-09-17

## TL;DR

This paper introduces a new 2D material, BaAs_3, which is stable, tunable in electronic properties, and capable of transitioning from semiconductor to metal via vacancy defects, promising for nanoelectronics.

## Contribution

The study reports the discovery and characterization of a stable, layered 2D BaAs_3 with tunable electronic properties and vacancy-induced phase transition, a novel addition to 2D materials.

## Key findings

- BaAs_3 is kinetically and thermally stable as a 2D material.
- Monolayer and bilayer BaAs_3 have narrow indirect band gaps of 0.87 eV and 0.40 eV.
- Vacancy defects can induce a semiconductor-metal transition in BaAs_3.

## Abstract

Searching for novel two-dimensional (2D) materials is highly desired in the field of nanoelectronics. We here propose a new 2D crystal barium tri-arsenide ($\mathrm{BaAs_3}$) with a series of encouraging functionalities. Being kinetically and thermally stable, the monolayer and bilayer forms of $\mathrm{BaAs_3}$ possess narrow indirect band gaps of 0.87 eV and 0.40 eV, respectively, with high hole mobilities on the order of ~$\mathrm{10^3\ cm^{2}\,V^{-1}\,s^{-1}}$. The electronic properties of 2D $\mathrm{BaAs_3}$ can be manipulated by controlling the layer thickness. The favorable cleavage energy reveals that layered $\mathrm{BaAs_3}$ can be produced as a freestanding 2D material. Furthermore, by introducing vacancy defects monolayer $\mathrm{BaAs_3}$ can be transformed from a semiconductor to a metal. 2D $\mathrm{BaAs_3}$ may find promising applications in nanoelectronic devices.

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Source: https://tomesphere.com/paper/1904.08742