Litcius/Paper detail

The <i>p</i>-orbital magnetic topological states on a square lattice

Jing-Yang You, Bo Gu, Gang Su

2021National Science Review25 citationsDOIOpen Access PDF

Abstract

Abstract Honeycomb or triangular lattices were extensively studied and thought to be proper platforms for realizing the quantum anomalous Hall effect (QAHE), where magnetism is usually caused by d orbitals of transition metals. Here we propose that a square lattice can host three magnetic topological states, including the fully spin-polarized nodal loop semimetal, QAHE and the topologically trivial ferromagnetic semiconductor, in terms of the symmetry and k · p model analyses that are material independent. A phase diagram is presented. We further show that the above three magnetic topological states can indeed be implemented in the two-dimensional (2D) materials ScLiCl5, LiScZ5 (Z=Cl, Br) and ScLiBr5, respectively. The ferromagnetism in these 2D materials is microscopically revealed from p electrons of halogen atoms. This present study opens a door to explore the exotic topological states as well as quantum magnetism from p-orbital electrons by means of the material-independent approach.

Topics & Concepts

MagnetismPhysicsFerromagnetismCondensed matter physicsElectronPhase diagramQuantum anomalous Hall effectSquare latticeLattice (music)Topology (electrical circuits)Atomic orbitalQuantum phasesSquare (algebra)Topological orderHoneycombSymmetry (geometry)Hexagonal latticeQuantumTopological insulatorQuantum mechanicsMagnetic monopoleQuantum Hall effectTopological degeneracyFermionPhase transitionTopological Materials and PhenomenaChemical and Physical Properties of Materials2D Materials and Applications