The systematic study on the stability and superconductivity of Y-Mg-H compounds under high pressure

Abstract

Motivated by recent discovery of yttrium-based high-temperature ternary superconducting hydrides (e.g., CaYH12, LaYH12, and ScYH6), we have employed evolutionary algorithm and first-principles calculations to comprehensively examine the structural stability and superconductivity of the YMgHx system at high pressure. The hydrogen content x and the pressure are both important factors in the stability of these candidate structures. We find that the stability of hydrogen-rich materials frequently necessitates higher pressure. For instance, the pressures to stabilize P4/mmm-YMgH8 and Cmmm-YMgH12 are both more than 250 GPa. Hydrogen-less materials, such as I41/amd-YMgH2 and P63/mmc-YMgH3, can be stable at pressures as low as 100 GPa. In addition, we find a metastable structure for YMgH6 with the same space group as the P4/mmm-YMgH8. A metastable sodalite-like face-centered cubic (FCC) structure is also found in YMgH12. These four clathrate structures of P4/mmm-YMgH6, P4/mmm-YMgH8, Cmmm-YMgH12, and Fd3m-YMgH12 is made up of H14, H18, H24, and H24 cages, respectively, in which the H-H pair exhibits weak covalent bonding. According to phonon calculations, P4/mmm-YMgH6 and P4/mmm-YMgH8 require a pressure of 300 GPa to maintain dynamic stability, however Cmmm-YMgH12 and Fd3m-YMgH12 can maintain dynamic stability at pressures of 200 GPa and 250 GPa, respectively. Electron-phonon coupling calculations indicate that they might be potential high-temperature superconductors, with superconductivity intimately linked to the H cage structure. The sodalite structure Fd3m-YMgH12 has a Tc value of 190 K and a strong electron-phonon coupling constant of 2.18.