Superconducting band stabilizing superconductivity in MgB2

TL;DR

This paper demonstrates that MgB2's superconductivity is linked to a specific narrow band with special symmetry, and introduces a nonadiabatic group-theoretical model explaining Cooper pair stabilization via crystal-spin-1 bosons.

Contribution

It identifies a particular superconducting band in MgB2 and proposes a novel nonadiabatic model that explains Cooper pair formation through crystal-spin-1 bosons.

Findings

MgB2 has a narrow superconducting band with special symmetry.

Superconductivity is connected to the presence of such superconducting bands.

Crystal-spin-1 bosons mediate Cooper pair formation, influencing Tc.

Abstract

It is shown that the superconducting intermetallic compound MgB2 possesses a narrow, partly filled "superconducting band" with Wannier functions of special symmetry in its band structure. This result corroborates previous observations about the band structures of numerous superconductors and non-superconductors showing that evidently superconductivity is always connected with such superconducting bands. These findings are interpreted in the framework of a nonadiabatic extension of the Heisenberg model. Within this new group-theoretical model of correlated systems, Cooper pairs are stabilized by a nonadiabatic mechanism of constraining forces effective in narrow superconducting bands. The formation of Cooper pairs in a superconducting band is mediated by the energetically lowest boson excitations in the considered material that carry the crystal spin-angular momentum 1 x h-bar. These crystal-spin-1 bosons are proposed to determine whether the material is a conventional low-Tc or a high-Tc superconductor. This interpretation provides the electron-phonon mechanism that enters the BCS theory in conventional superconductors.