Thermodynamic Origins of Structural Metastability in Two-Dimensional Black Arsenic

TL;DR

This study investigates the thermodynamic stability of two-dimensional black arsenic, revealing its metastability conditions, transformation behavior under pressure and temperature, and methods to control its thickness for potential nanoelectronic applications.

Contribution

It provides the first detailed thermodynamic analysis of black arsenic's structural metastability and demonstrates control over its stability and thickness through pressure and thermal annealing.

Findings

Black arsenic survives below 0.7 GPa before transforming to gray arsenic.

Thermal annealing at 300°C causes sublimation of black arsenic.

Theoretical calculations confirm experimental stability limits.

Abstract

Two-dimensional (2D) materials have aroused considerable research interests owing to their potential applications in nanoelectronics and optoelectronics. Thermodynamic stability of 2D structures inevitably affects the performance and power consumption of the fabricated nanodevices. Black arsenic (b-As), as a cousin of black phosphorus, has presented the extremely high anisotropy in physical properties. However, the systematic research on structural stability of b-As is still lack. Herein, we demonstrated the detailed analysis on structural metastability of the natural b-As, and determined its existence conditions in terms of two essential thermodynamic variables as hydrostatic pressure and temperature. Our results confirmed that b-As can only survive below 0.7 GPa, and then irreversibly transform to gray arsenic, in consistent with our theoretical calculations. Furthermore, thermal annealing strategy was developed to precisely control the thickness of b-As flake, and it sublimates at 300 oC. These results could pave the way for 2D b-As in many promising applications.