3D Dirac semimetals: current materials, design principles and predictions of new materials

Abstract

Design principles and novel predictions of new 3D Dirac semimetals are presented, along with the context of currently known materials. Current materials include those based on a topological to trivial phase transition, such as in TlBiSe2-xSx and Hg1-xCdxTe, Bi1-xSbx, Bi2-xInxSe3, and Pb1-xSnxSe. Some more recently revealed materials, Na3Bi and Cd3As2, are 3D Dirac semimetals in their native composition. The different design principles presented each yield novel predictions for new candidates. For Case I, 3D Dirac semimetals based on charge balanced compounds, BaAgBi, SrAgBi, YbAuSb, PtBi2 and SrSn2As2 are identified as candidates. For Case II, 3D Dirac semi-metals in analogy to graphene, BaGa2 is identified as a candidate, and BaPt and Li2Pt are discussed. For Case III, 3D Dirac semi-metals based on glide planes and screw axes, TlMo3Te3 and the AMo3X3 family in general (A=K, Na, In, Tl, X=Se,Te) as well as the Group IVb trihalides such as HfI3 are identified as candidates. Finally we discuss conventional intermetallic compounds with Dirac cones, and identify Cr2B as a potentially interesting material.