Hopping mechanism for superconductivity revealed by Density Functional Theory

TL;DR

This paper reveals a hopping mechanism underlying superconductivity in MgB2 and other compounds, using DFT analysis of cosine-shaped bands and their asymmetries, which are linked to the superconducting gap and Fermi surface nesting.

Contribution

It introduces a detailed analysis of cosine-shaped bands and their asymmetries, establishing a connection between hopping mechanisms and superconductivity in MgB2 and similar materials.

Findings

Cosine-shaped bands are linked to a hopping mechanism affecting superconductivity.

Band asymmetry correlates with the superconducting gap and Fermi surface nesting.

Analysis applies to other superconductors like CaC6 and LaH10.

Abstract

Cosine-shaped bands that occur in DFT-based electronic band structures for MgB2 are further analyzed with calculations along reciprocal directions parallel to the high symmetry G-A direction at regular intervals along G-M. Band degeneracies in close proximity to the Fermi surface (offset from G-A), do not emulate the degenerate bands along G-A. At the Fermi surface, bands split and align favorably for electron-hole pairing with the nodal inflection point located at the Fermi level. Tight-binding equations, including corrections to describe the observed asymmetry of a cosine-shaped band, can be compared to the secular equation obtained for Bloch orbitals of an infinite linear chain of atoms with two s-states. These equations show unequivocally that a hopping mechanism is associated with the cosine-shaped band asymmetry, an asymmetry strongly correlated with the superconducting gap and Fermi surface nesting. Intersections of folded Fermi surfaces and electronic band crossings provide avenues or pathways for electrons from the nested collection to drastically change velocity or momentum, resulting in scattering and disruption of nested, coherent behavior. Determination of cosine band asymmetry, also established for other two element superconductors such as CaC6 and LaH10, is relevant for interpretation of superconductivity mechanisms in many other multi-element compounds.