Lattice distortion induced first and second order topological phase transition in rectangular high-T c superconducting monolayer

Abstract

We theoretically study the lattice distortion induced first and second order topological phase transition in rectangular FeSexTe1-x monolayer. When compressing the lattice constant in one direction, our first principles calculation shows that the FeSexTe1-x undergoes a band inversion at point in a wide dopping range, say x∈(0.0,0.7), which ensures coexistence of the topological band state and the high-T c superconductivity. This unidirectional pressure also leads to the C4 symmetry breaking which is necessary for the monolayer FeSexTe1-x to support Majorana corner states in the either presence or absence of time-reversal symmetry. Particularly, we use k· p methods to fit the band structure from the first principles calculation and found that the edge states along the (100) and (010) directions have different Dirac energy due to C4 symmetry breaking. This is essential to obtain Majorana corner states in D class without concerning the details of the superconducting pairing symmetries and Zeeman form, which can potentially bring advantages in the experimental implementation.