Anisotropic mechanical properties and strain tuneable band-gap in single-layer SiP, SiAs, GeP and GeAs

TL;DR

This study uses density functional theory to analyze the anisotropic mechanical properties and strain-tunable electronic band-gaps of single-layer SiP, SiAs, GeP, and GeAs, revealing their potential for flexible electronic applications.

Contribution

It provides the first detailed analysis of mechanical responses and strain-induced band-gap tuning in these novel 2D materials using first-principles simulations.

Findings

Anisotropic mechanical responses with higher properties along zigzag direction.

Stretchability of these monolayers exceeds that of graphene and h-BN.

Strain can effectively narrow the electronic band-gaps.

Abstract

In this investigation, we conducted density functional theory simulations to explore the mechanical responses of single-layer GeP, GeAs, SiP and SiAs. In particular, we explored the possibility of band-gap engineering in these 2D structures through different mechanical loading conditions.First-principles results of uniaxial tensile simulations confirm anisotropic mechanical responses of these novel 2D structures, with considerably higher elastic modulus, tensile strength and stretchability along the zigzag direction as compared with the armchair direction. Notably, the stretchability of considered monolayers along the zigzag direction was found to be slightly higher than that of the single-layer graphene and h-BN. The electronic band-gaps of energy minimized single-layer SiP, SiAs, GeP and GeAs were estimated by HSE06 method to be 2.58 eV, 2.3 eV, 2.24 eV and 1.98 eV, respectively. Our results highlight the strain tuneable band-gap character in single-layer SiP, SiAs, GeP and GeAs and suggest that various mechanical loading conditions can be employed to finely narrow the electronic band-gaps in these structures.