Topological semimetal phases manifested in transition metal dichalcogenides intercalated with 3d metals

Abstract

In the search for stable topological semimetals with clean band profiles, we have screened all the 3d metal-intercalated transition-metal dichalcogenides (3dI-TMDCs) by performing hybrid-functional-based ab initio calculations. Two classes of topological materials featuring twelve Weyl nodes in the kz=0 plane (without spin-orbit interactions) are identified: (a) time-reversal-breaking Weyl semimetals VT3X6 (ferromagnetic) and (b) spinless Weyl semimetals MnT3X6 (nonmagnetic), where T=Nb, Ta; X=S, Se. VNb3S6, prototypical of class (a), is half-metallic with only two bands crossing at the Fermi level to form Weyl nodes. MnNb3S6 in the nonmagnetic phase is essentially a spinless version of VNb3S6 featuring an equally clean and simple band profile. Although the space group symmetry (P6322) implies that the degeneracy between the two bands is lifted for k away from the Weyl nodes, the gap remains extremely small ( 0.1 meV) along a loop connecting the Weyl nodes. This quasi-nodal-line degeneracy is explained in terms of the quasi-mirror symmetry of the lattice, induced by the in-plane twofold rotation axes, and the specific orbital nature of the bands. 3dI-TMDCs are chemically and thermally stable stoichiometric compounds containing no toxic elements and are a viable platform for the study of topological condensed-matter physics.