Topological States in Chevrel Phase Materials from First-principle Calculations
Abstract
Chevrel phase materials form a family of ternary molybdenum chalcogenides with a general chemical formula Ax Mo6X8 (A = metal elements, X = chalcogen). The variety of A atoms makes a large number of family members and leads to many tunable physical properties, such as the superconductivity, thermoelectricity and the ionic conductivity. In this work, we have further found various nontrivial band topological states in these materials by using first-principle calculations. The compounds having time-reversal symmetry, such as BaMo6 S8, SrMo6 S8, and Mo6 S8, are topological insulators in both of the R3 and P1 phases, whereas EuMo6 S8 within ferromagnetic state, it is an axion insulator in the R3 phase and a trivial one in the P1 phase. This indicates that the change of A ions can modify the chemical potential, lattice distortion, and magnetic orders, which offers a unique way to influence the topological states and other properties. We hope this work can stimulate further studies of Chevrel phase materials to find more intriguing phenomena, such as topological superconducting states and Majorana modes.
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