Assemble superhydrides with non-integer H/Metal ratios on metal templates

Metal superhydrides such as CaH6, YH9 and LaH10 et. al., show a good potential to achieve room-temperature superconductivity and have been studied intensively in the past decade. With the help of diverse crystal structure prediction (CSP) methods, structures of binary superhydrides MHn with varying metals across the periodic table and many compositions up to n=24 have been thoroughly searched, and their properties and superconductivity thoroughly studied, without bringing any unexpected breakthrough. While the usual chemical space spanned by the integer H/M ratios n has almost been exhausted and many ternary superhydrides, consisting of two metals, have also been explored, there are large areas in the composition space that have not been systematically explored. For example, no explicit rule excludes a non-integer H/M ratio in the binary. However, a thorough structure search of MxHy, as well as ternary superhydrides, is a tremendous task and cannot reach the extent of the study of binary superhydrides with current CSP methods. Based on our recent template theory that explains the stability of metal superhydrides as the result of a "template effect" of metal lattices, we conducted a systematic search of MxHy and ternary superhydrides in two steps including the identification of the efficient templates and the assembly of superhydrides. With the help of this method, we identified many new superhydrides, including more than 30 complex clathrate superhydrides, many have more than 50 atoms in the primitive cell. The method also shows good potential to search ternary superhydrides in large scale.