Strongly correlated electrons

TL;DR

This review covers theoretical models and concepts for strongly correlated electron systems, emphasizing phenomena like quantum phase transitions, electron localization, unconventional superconductivity, and fractional charges in various materials.

Contribution

It provides a comprehensive overview of models and phenomena in strongly correlated electrons, including new insights into localization, quantum phase transitions, and fractionalization in complex materials.

Findings

Analysis of magnetic and superconducting instabilities in Kondo systems

Discussion of partial localization of 5f electrons and its effects

Exploration of fractional charges in frustrated lattices

Abstract

We review theoretical concepts and models for materials with strongly correlated d- or f electrons. We discuss low-energy effective models and the renormalized band method for Ce-based Kondo lattice systems. They are applied to the analysis of associated magnetic and superconducting instabilities. In addititon quantum phase transitions are investigated. Special emphasis is given to the partial localisation of 5f electrons in U compounds and its consequences for unconventional superconductivity. Wigner crystallisation in the homogeneous electron gas and its generalisation to 4f pnictide and 3d oxide materials is covered extensively. We analyse simultaneous charge order and lattice instabilities in geometrically frustrated V-oxide spinels. Using a spinless fermion model we also discuss the emergence of fractional charges in the frustrated pyrochlore or checkerboard lattice. Finally we focus on the signature of strong electronic correlations in high-energy excitations.