High Temperature Superconductivity: the explanation

TL;DR

This paper discusses the bipolaron theory of high-temperature superconductivity, proposing that a combination of strong electron correlations and finite-range electron-phonon interactions explains experimental observations.

Contribution

It introduces a development in bipolaron theory emphasizing the role of combined electron correlations and finite-range EPI in high-temperature superconductivity.

Findings

Bipolaron theory aligns with key experimental data

Finite-range EPI is crucial for pairing mechanism

Strong correlations complement electron-phonon interactions

Abstract

Soon after the discovery of the first high temperature superconductor by Georg Bednorz and Alex Mueller in 1986 the late Sir Nevill Mott answering his own question "Is there an explanation?" [Nature v 327 (1987) 185] expressed a view that the Bose-Einstein condensation (BEC) of small bipolarons, predicted by us in 1981, could be the one. Several authors then contemplated BEC of real space tightly bound pairs, but with a purely electronic mechanism of pairing rather than with the electron-phonon interaction (EPI). However, a number of other researchers criticized the bipolaron (or any real-space pairing) scenario as incompatible with some angle-resolved photoemission spectra (ARPES), with experimentally determined effective masses of carriers and unconventional symmetry of the superconducting order parameter in cuprates. Since then the controversial issue of whether the electron-phonon interaction (EPI) is crucial for high-temperature superconductivity or weak and inessential has been one of the most challenging problems of contemporary condensed matter physics. Here I outline some developments in the bipolaron theory suggesting that the true origin of high-temperature superconductivity is found in a proper combination of strong electron-electron correlations with a significant finite-range (Froehlich) EPI, and that the theory is fully compatible with the key experiments.