How Compressed Hydrides Produce Room Temperature Superconductivity

Abstract

The 2014-2015 prediction, discovery, and confirmation of record high temperature superconductivity above 200K in H3S, followed by the 2018 extension to superconductivity in the 250-280K range in lanthanum hydride, marks a new era in the longstanding quest for room temperature superconductivity: quest achieved, at the cost of supplying 1.5-2 megabars of pressure. Predictions of numerous high temperature superconducting metal hydrides XHn (X=metal) have appeared, but are providing limited understanding of what drives the high transition temperature Tc, or what limits Tc. We apply an opportunistic atomic decomposition of the coupling function to show, first, that the X atom provides coupling strength as commonly calculated, but is it irrelevant for superconductivity; in fact, it is important for analysis that its contribution is neglected. Five XHn compounds, predicted to have Tc in the 150-300K range, are analyzed consistently for their relevant properties, revealing some aspects that confront conventional wisdom. A phonon frequency -- critical temperature (ω2-Tc) phase diagram is obtained that reveals a common phase instability limiting Tc at the low pressure range of each compound. The hydrogen scattering strength is identified and found to differ strongly over the hydrides. A quantity directly proportional to Tc in these hydrides is identified.