Quantum Criticality in a Layered Iridate
Abstract
Iridates provide a fertile ground to investigate correlated electrons in the presence of strong spin-orbit coupling. Bringing these systems to the proximity of a metal-insulator quantum phase transition is a challenge that must be met to access quantum critical fluctuations with charge and spin-orbital degrees of freedom. Here, electrical transport and Raman scattering measurements provide evidence that a metal-insulator quantum critical point is effectively reached in 5 % Co-doped SrIrO with high structural quality. The dc-electrical conductivity shows a linear temperature dependence that is successfully captured by a model involving a Co acceptor level at the Fermi energy that becomes gradually populated at finite temperatures, creating thermally-activated holes in the lower Hubbard band. The so-formed quantum critical fluctuations are exceptionally heavy and the resulting electronic continuum couples with an optical phonon at all temperatures. The magnetic order and pseudospin-phonon coupling are preserved under the Co doping. This work brings quantum phase transitions, iridates and heavy-fermion physics to the same arena.
Cite
@article{arxiv.2104.01098,
title = {Quantum Criticality in a Layered Iridate},
author = {Kousik Samanta and Jean C. Souza and Danilo Rigitano and Adimir I. Morales and Pascoal G. Pagliuso and Eduardo Granado},
journal= {arXiv preprint arXiv:2104.01098},
year = {2021}
}
Comments
30 pages, 5 main figures, 7 supplementary figures; to appear in Communications Physics