Superconductivity at 253 K in lanthanum-yttrium ternary hydrides

Abstract

Polyhydrides offer intriguing perspectives as high-temperature superconductors. Here we report the high-pressure synthesis of a series of lanthanum-yttrium ternary hydrides: cubic hexahydride (La,Y)H6 with a critical temperature TC = 237 +/- 5 K and decahydrides (La,Y)H10 with a maximum TC ~253 K and an extrapolated upper critical magnetic field BC2(0) up to 135 T at 183 GPa. This is one of the first examples of ternary high-TC superconducting hydrides. Our experiments show that a part of the atoms in the structures of recently discovered Im3m-YH6 and Fm3m-LaH10 can be replaced with lanthanum (~70 %) and yttrium (~25 %), respectively, with a formation of unique ternary superhydrides containing incorporated La@H24 and Y@H32 which are specific for Im3m-LaH6 and Fm3m-YH10. Ternary La-Y hydrides were obtained at pressures of 170-196 GPa via the laser heating of P63/mmc lanthanum-yttrium alloys in the ammonia borane medium at temperatures above 2000 K. A novel tetragonal (La,Y)H4 was discovered as an impurity phase in synthesized cubic (La,Y)H6. The current-voltage measurements show that the critical current density JC in (La,Y)H10 may exceed 2500 A/mm2 at 4.2 K, which is comparable with that for commercial superconducting wires such as NbTi, Nb3Sn. Hydrides that are unstable in a pure form may nevertheless be stabilized at relatively low pressures in solid solutions with superhydrides having the same structure.