Realization of unpinned two-dimensional dirac states in antimony atomic layers

Two-dimensional (2D) Dirac states with linear dispersion have been observed in graphene and on the surface of topological insulators. 2D Dirac states discovered so far are exclusively pinned at high-symmetry points of the Brillouin zone, for example, surface Dirac states at (Gamma) over bar in topological insulators Bi2Se(Te)(3) and Dirac cones at K and K' points in graphene. The low-energy dispersion of those Dirac states are isotropic due to the constraints of crystal symmetries. In this work, we report the observation of novel 2D Dirac states in antimony atomic layers with phosphorene structure. The Dirac states in the antimony films are located at generic momentum points. This unpinned nature enables versatile ways such as lattice strains to control the locations of the Dirac points in momentum space. In addition, dispersions around the unpinned Dirac points are highly anisotropic due to the reduced symmetry of generic momentum points. The exotic properties of unpinned Dirac states make antimony atomic layers a new type of 2D Dirac semimetals that are distinct from graphene.

Automated summary

Novel 2D Dirac states have been observed in antimony atomic layers with a phosphorene structure. These unpinned Dirac states are located at generic momentum points and can be controlled in momentum space using lattice strains. The dispersions around the unpinned Dirac points are highly anisotropic due to the reduced symmetry of generic momentum points.