A Unified Theory for the Cuprates, Iron-Based and Similar Superconducting Systems: Application for Spin and Charge Excitations in the Hole-Doped Cuprates

TL;DR

This paper develops a unified theoretical framework for cuprates and iron-based superconductors, explaining their spin and charge excitations through auxiliary particles and a Lagrange Bose field, aligning well with experimental observations.

Contribution

It introduces a novel unified theory based on common electronic features, using auxiliary particles and a Lagrange Bose field to describe excitations and superconductivity in these materials.

Findings

Calculated resonance mode matches experimental data in hole-doped cuprates.

Resonance mode correlates with the pairing gap on Fermi arcs.

Theory explains inhomogeneities and pairing mechanisms in superconductors.

Abstract

A unified theory for the cuprates and the iron-based superconductors is derived on the basis of common features in their electronic structures including quasi-two-dimensionality, and the large-U nature of the electron orbitals close to E_F (smaller-U hybridized orbitals reside at bonding and antibonding states away from E_F). Consequently, low-energy excitations are described in terms of auxiliary particles, representing combinations of atomic-like electron configurations, rather than electron-like quasiparticles. The introduction of a Lagrange Bose field is necessary to enable the treatments of these auxiliary particles as bosons or fermions. The condensation of the bosons results in static or dynamical inhomogeneities, and consequently in a commensurate or an incommensurate resonance mode. The dynamics of the fermions determines the charge transport, and their strong coupling to the Lagrange-field bosons results in pairing and superconductivity. The calculated resonance mode in hole-doped cuprates agrees with the experimental results, and is shown to be correlated with the pairing gap on the Fermi arcs.