Metal Atom (Dis)Order and Superconductivity in YCaHn (n=8-20) High-Pressure Superhydrides

Abstract

High-pressure superhydrides have attracted much attention due to their high superconducting critical temperatures (Tcs). Herein, density functional theory (DFT) calculations are used to study the structures and properties, including potential for metal atom disorder and doping-enhanced Tc, within Y-Ca superhydrides with YCaHn (n=8-20) compositions. For YCaH8 numerous phases that differed in the arrangement of the metal atoms were found to be nearly isoenthalpic, suggesting the importance of configurational entropy on stability. The equimolar ratio of the two metal atoms brought the Fermi level to a peak in the density of states, enhancing Tc to 149~K and 170~K for P4/mmm and Cmmm YCaH8, respectively, at 180~GPa within the isotropic Eliashberg formalism. YCaH12 was also predicted to be disordered, however the Tcs of the ordered variants spanned a wide range from 105-253~K at 200~GPa, showing that doping could either mildly enhance or drastically reduce Tc from that of the parent compounds. For YCaH18 and YCaH20, only a single dynamically stable superhydride was predicted, which we attribute to the differences in the structures of the stable binary parents.