Generalized Triple-Component Fermions: Lattice Model, Fermi arcs, and Anomalous Transport

Abstract

We generalize the construction of time-reversal symmetry-breaking triple-component semimetals, transforming under the pseudospin-1 representation, to arbitrary (anti-)monopole charge 2 n, with n=1,2,3 in the crystalline environment. The quasiparticle spectra of such systems are composed of two dispersing bands with pseudospin projections ms= 1 and energy dispersions E k= α2n k2n +v2z k2z, where k=k2x+k2y, and one completely flat band at zero energy with ms=0. We construct simple tight-binding models for such spin-1 excitations on a cubic lattice and address the symmetries of the generalized triple-component Hamiltonian. In accordance to the bulk-boundary correspondence, triple-component semimetals support 2 n branches of topological Fermi arc surface states and also accommodate a large anomalous Hall conductivity (in the xy plane), given by σ 3Dxy 2 n × the separation of the triple-component nodes (in units of e2/h). Furthermore, we compute the longitudinal magnetoconductivity, planar Hall conductivity, and magneto thermal conductivity in these systems, which increase as B2 for sufficiently weak magnetic fields (B) due to the nontrivial Berry curvature in the medium. A generalization of our construction to arbitrary integer spin systems is also highlighted.