Progress, problems and prospects of room-temperature superconductivity

TL;DR

This paper reviews recent advances in room-temperature superconductivity achieved in high-pressure hydrides, highlighting experimental findings that support electron-phonon pairing mechanisms and discuss unusual properties of these materials.

Contribution

It provides a comprehensive analysis of galvanomagnetic studies on polyhydrides, emphasizing their superconducting properties and complex electron interactions at megabar pressures.

Findings

Superconductivity confirmed by resistance drops and diamagnetic screening.

Electron-phonon mechanism supported by isotope and impurity effects.

Unusual linear temperature dependencies observed in critical fields and resistance.

Abstract

Discovery of superconductivity at megabar (MB) pressures in hydrogen sulfide H3S, then in metal polyhydrides, starting with binary, LaH10, etc., and ending with ternary ones, including (La, Y)H10, revolutionized the field of condensed matter physics. These discoveries strengthen hopes for solution of the century-old problem of creating materials that are superconducting at room temperature. In experiments performed over the past 5 years at MB pressures, in addition to the synthesis of hydrides itself, their physical properties were studied using optical, X-ray and Mossbauer spectroscopy, as well as galvanomagnetic measurement techniques. This paper presents the major results of galvanomagnetic studies, including measurements in high static (up to 21T) and pulsed (up to 70T) magnetic fields. Measurements of resistance drops to vanishingly small level at temperatures below the critical Tc value, a decrease in the critical temperature Tc with increasing magnetic field, as well as diamagnetic screening, indicate the superconducting state of the polyhydrides. The results of measurements of the isotope effect, together with the effect of magnetic impurities on Tc, indicate the electron-phonon mechanism of electron pairing. However, electron-electron correlations in polyhydrides are by no means small, both in the superconducting and normal states. It is possible that this is precisely what accounts for the unusual properties of polyhydrides that have not yet received a satisfactory explanation, such as a linear temperature dependence of the second critical field Hc2(T), a linear dependence of resistance R(T), and a linear magnetoresistance, very similar to that discovered by P. L. Kapitza in 1929.