Superconducting properties of lithium-decorated bilayer graphene

TL;DR

This paper provides a theoretical analysis of superconductivity in lithium-decorated bilayer graphene, showing enhanced thermodynamic properties and indicating strong-coupling behavior beyond BCS theory.

Contribution

It offers the first detailed Eliashberg formalism-based study of superconductivity in lithium-decorated bilayer graphene, highlighting enhanced critical temperature and strong-coupling effects.

Findings

Critical temperature up to ~15 K.

Thermodynamic ratios exceed BCS predictions.

Strong-coupling regime indicated by analysis.

Abstract

Present study provides a comprehensive theoretical analysis of the superconducting phase in selected lithium-decorated bilayer graphene nanostructures. The numerical calculations, conducted within the Eliashberg formalism, give quantitative estimations of the most important thermodynamic properties such as the critical temperature, specific heat, critical field and others. It is shown that discussed lithium-graphene systems present enhancement of their thermodynamic properties comparing to the monolayer case e.g. the critical temperature can be raised to $\sim 15$ K. Furthermore, estimated characteristic thermodynamic ratios exceed predictions of the Bardeen-Cooper-Schrieffer theory suggesting that considered lithium-graphene systems can be properly analyzed only within the strong-coupling regime.