Phase evolution and superconductivity enhancement in Se-substituted MoTe2 thin films

Abstract

The strong spin-orbit coupling (SOC) and numerous crystal phases in few-layer transition metal dichalcogenides (TMDCs) MX2 (M=W, Mo, and X=Te, Se, S) has led to a variety of novel physics, such as Ising superconductivity and quantum spin Hall effect realized in monolayer 2H- and Td-MX2, respectively. Consecutive tailoring of the MX2 structure from 2H to Td phase may realize the long-sought topological superconductivity in one material system by incorporating superconductivity and quantum spin Hall effect together. In this work, by combing Raman spectrum, X-ray photoelectron spectrum (XPS), scanning transmission electron microscopy imaging (STEM) as well as electrical transport measurements, we demonstrate that a consecutively structural phase transitions from Td to 1T' to 2H polytype can be realized as the Se-substitution concentration increases. More importantly, the Se-substitution has been found to notably enhance the superconductivity of the MoTe2 thin film, which is interpreted as the introduction of the two-band superconductivity. The chemical constituent induced phase transition offers a new strategy to study the s+- superconductivity and the possible topological superconductivity as well as to develop phase-sensitive devices based on MX2 materials.