Exploration of stable compounds, crystal structures, and superconductivity in the Be-H system

Abstract

Using first-principles variable-composition evolutionary methodology, we explored the high-pressure structures of beryllium hydrides between 0 and 400 GPa. We found that BeH2 remains the only stable compound in this pressure range. The pressure-induced transformations are predicted as Ibam → P3m1 → R3m → Cmcm → P4/nmm, which occur at 24, 139, 204 and 349 GPa, respectively. P3m1 and R3m structures are layered polytypes based on close packings of H atoms with Be atoms filling octahedral voids in alternating layers. Cmcm and P4/nmm structures have 3D-networks of strong bonds, but also feature rectanular and squre, respectively, layers of H atoms with short H-H distances. P3m1 and R3m are semiconductors while Cmcm and P4/nmm are metallic. We have explored superconductivity of both metallic phases, and found large electron-phonon coupling parameters of λ =0.63 for Cmcm (resulting in a Tc of 32.1-44.1 K) at 250 GPa and λ =0.65 for P4/nmm (Tc = 46.1-62.4 K) at 400 GPa. The dependence of Tc on pressure indicates that Tc initially increases to a maximum of 45.1 K for Cmcm at 275 GPa and 97.0 K for P4/nmm at 365 GPa, and then decreases with increasing pressure for both phases.