High-throughput computational search for two-dimensional binary compounds: Energetic stability versus synthesizability of three-dimensional counterparts

Abstract

Using first principles calculations, the energetic stability of two-dimensional (2D) binary compounds XY is investigated, where X and Y indicate the metallic element from Li to Pb in the periodic table. Here, 1081 compounds in the buckled honeycomb (BHC), buckled square, B2, L10, and Bh structures are studied. For the compounds that have negative formation energy in the BHC structure or the compounds that can have the Bh structure, the phonon dispersions of the 2D structures are also calculated. We demonstrate that (i) a negative formation energy is neither a sufficient nor necessary condition for yielding the dynamical stability of 2D compounds; and (ii) if a compound in the Bh structure has been synthesized experimentally, that in the BHC structure is dynamically stable.