Dirac node lines in a two-dimensional bipartite square lattice

Abstract: As a new type of quantum matter, Dirac node line (DNL) semimetals are currently attracting widespread interest in condensed matter physics and material science. The DNL featured by a closed line consisting of linear band crossings in the lattice momentum space are mostly predicted in three-dimensional materials. Here, we propose tight-binding (TB) models of pz/px,y or pz/s orbitals in a two-dimensional (2D) bipartite square lattice for the 2D version of DNL semimetals. The DNL states in these models are caused by the inversion of the bands with different symmetries and thus robust again spin-orbit coupling (SOC). By means of first-principles calculations, we demonstrate two candidate 2D materials of these models: Be2C and BeH2 monolayers, which have Fermi circles centered at {\Gamma} (0,0) and K (1/2, 1/2) points, respectively. The topological nontriviality is verified by the non-zero topological invariant and the edge states. This work opens an avenue for design of 2D DNL semimetals.