Nature of Correlated Motion of Electrons in the Parent Cobaltate Superconductors

TL;DR

This study uses angle-resolved photoemission spectroscopy to investigate the electron motion in cobaltate superconductors, revealing heavy quasiparticles and significant deviations from conventional superconductivity models, indicating a potentially high-temperature superconducting class.

Contribution

First direct measurement of microscopic electron motion in cobaltate superconductors, uncovering heavy quasiparticles and deviations from BCS theory.

Findings

Large hole-like Fermi surface consistent with Luttinger theorem

Heavy quasiparticles with significantly altered electron dynamics

Evidence of cobaltates as a high-temperature superconductor class

Abstract

Recently discovered class of cobaltate superconductors (Na0.3CoO2.nH2O) is a novel realization of interacting quantum electron systems in a triangular network with low-energy degrees of freedom. We employ angle-resolved photoemission spectroscopy to uncover the nature of microscopic electron motion in the parent superconductors for the first time. Results reveal a large hole-like Fermi surface (consistent with Luttinger theorem) generated by the crossing of super-heavy quasiparticles. The measured quasiparticle parameters collectively suggest a two orders of magnitude departure from the conventional Bardeen-Cooper-Schrieffer electron dynamics paradigm and unveils cobaltates as a rather hidden class of relatively high temperature superconductors.