Sr-Doped Superionic Hydrogen Glass: Synthesis and Properties of SrH22

Recently, several research groups announced reaching the point of metallization of hydrogen above 400 GPa. Despite notable progress, detecting superconductivity in compressed hydrogen remains an unsolved problem. Following the mainstream of extensive investigations of compressed metal polyhydrides, here small doping of molecular hydrogen by strontium is demonstrated to lead to a dramatic reduction in the metallization pressure to approximate to 200 GPa. Studying the high-pressure chemistry of the Sr-H system, the formation of several new phases is observed: C2/m-Sr3H13, pseudocubic SrH6, SrH9 with cubic F4 over bar 3m$F\bar{4}3m$-Sr sublattice, and pseudo tetragonal superionic P1-SrH22, the metal hydride with the highest hydrogen content (96 at%) discovered so far. High diffusion coefficients of hydrogen in the latter phase D-H = 0.2-2.1 x 10(-9) m(2) s(-1) indicate an amorphous state of the H-sublattice, whereas the strontium sublattice remains solid. Unlike Ca and Y, strontium forms molecular semiconducting polyhydrides, whereas calcium and yttrium polyhydrides are high-T-C superconductors with an atomic H sublattice. The discovered SrH22, a kind of hydrogen sponge, opens a new class of materials with ultrahigh content of hydrogen.

Automated summary

By doping molecular hydrogen with a small amount of strontium, the metallization pressure of hydrogen can be dramatically reduced to approximately 200 GPa. Several new phases were discovered in the high-pressure chemistry of the Sr-H system, with SrH22 being the metal hydride with the highest hydrogen content discovered so far.