Strain-induced topological phase transition in two-dimensional platinum ditelluride

Abstract

Topological phase transition is a hot topic in condensed matter physics and computational material science. Here, we investigate the electronic structure and phonon dispersion of the two-dimensional (2D) platinum ditelluride (PtTe2) using the density functional theory. It is found that the PtTe2 monolayer is a trivial insulator with an indirect band gap of 0.347eV. Based on parity analysis, the biaxial tensile strain can drive the topological phase transition. As the strain reaches 19.3%, PtTe2 undergoes a topological phase transition, which changes from a trivial band insulator to a topological insulator with Z2=1. Unlike conventional honeycomb 2D materials with topological phase transition, which gap closes at K points, the strained PtTe2 monolayer becomes gapless at M points under critical biaxial strain. The band inversion leads the switch of the parities near the Fermi level, which gives rise to the topological phase transition. The novel monolayer PtTe2 has a potential application in the field of micro-electronics.

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