First-principles study on the high-Tc superconductivity of Mg-Ti-H ternary hydrides up to the liquid-nitrogen temperature range under high pressures

Abstract

Ternary hydrides have emerged as the primary focus of the new wave of research into superconducting hydrides. In this work, Mg-Ti-H ternary hydrides are explored under high pressures up to 300 GPa using the prediction method of the particle swarm optimization algorithm combined with first-principles calculations. Two new structures, P4/nmm-MgTiH6 and Pmm2-Mg3TiH6, are identified to be thermodynamically stable at both 200 GPa and 300 GPa. Thermodynamically stable structures of Mg3TiH12 are also identified, whose space groups are R3/m at 200 GPa and Pm3m at 300 GPa, respectively. Among these Mg-Ti-H structures, P4/nmm-MgTiH6 achieves a record-high Tc of 81.9 K at 170 GPa, exceeding the boiling point of liquid nitrogen. Such a high Tc is primarily attributed to strong electron-phonon coupling (EPC) driven by low-frequency acoustic phonon modes, with the EPC strength reaching a large value of 1.54. The Tc of Pm3m-Mg3TiH12 is predicted to be 40 K at 300 GPa. Furthermore, element substitution of Zr(Hf) for Ti achieves considerable enhancement of superconducting properties in our predicted hydrogen-rich and high-symmetric crystal structures, i.e., P4/nmm-MgTiH6 and Pm3m-Mg3TiH12. The high pressure required for dynamical stability is lowered to 100 GPa in both Pm3m-Mg3ZrH12 and Pm3m-Mg3HfH12, and to 90 GPa and 120 GPa for P4/nmm-MgZrH6 and P4/nmm-MgHfH6, respectively. Particularly, the electronic structure near the Fermi level is significantly modified in the P4/nmm-MgHfH6 phase, and pronounced softening of low-frequency acoustic phonon modes occurs. As a result, the EPC strength is enhanced to 1.72, leading to a higher Tc of 86 K.