From semiconductor to metal: A reversible tuning of electronic properties of mono to multilayered SnS2 under applied strain

Abstract

Controlled variation of the electronic properties of 2D materials by applying strain has emerged as a promising way to design materials for customized applications. Using first principles density functional theory calculations, we show that while the electronic structure and indirect band gap of SnS2 do not change significantly with the number of layers, they can be reversibly tuned by applying biaxial tensile (BT), biaxial compressive (BC), and normal compressive (NC) strains. Mono to multilayered SnS2 exhibit a reversible semiconductor to metal transition (S-M) at strain values of 0.17, -0.26, and -0.24 under BT, BC, and NC strains, respectively. Due to weaker interlayer coupling, the critical strain value required to achieve S-M transition in SnS2 under NC strain is much higher than for MoS2. The S-M transition for BT, BC, and NC strains is caused by the interaction between the S-pz and Sn-s, S-px/py and Sn-s, and S-pz and Sn-s orbitals, respectively.