Electronic structures and topological properties of TeSe2 monolayers

The successfully experimental fabrication of two-dimensional Te monolayer films Phys. Rev. Lett. 119 106101 (2017)] has promoted the researches on the group-VI monolayer materials. In this work, the electronic structures and topological properties of a group-VI binary compound of TeSe₂ monolayers are studied based on the density functional theory and Wannier function method. Three types of structures, namely, α-TeSe₂, β-TeSe₂, and γ-TeSe₂, are proposed for the TeSe₂ monolayer among which the α-TeSe₂ is found being the most stable. All the three structures are semiconductors with indirect band gaps. Very interestingly, the γ-TeSe₂ monolayer becomes a quantum spin Hall (QSH) insulator with a global nontrivial energy gap of 0.14 eV when a 3.5% compressive strain is applied. The opening of the global band gap is understood by the competition between the decrease of the local band dispersion and the weakening of the interactions between the Se p_x, p_y orbitals and Te p_x, p_y orbitals during the process. Our work realizes topological states in the group-VI monolayers and promotes the potential applications of the materials in spintronics and quantum computations.