Unraveling the unusually high electrical conductivity of the delafossite metal PdCoO2

Abstract

The prototypical delafossite metal PdCoO2 has been the subject of intense interest for hosting exotic transport properties. Using first-principles transport calculations and theoretical modeling, we reveal that the high electrical conductivity of PdCoO2 at room temperature originates from the contributions of both high Fermi velocities, enabled by Pd 4dz2-5s hybridization, and exceptionally weak electron-phonon coupling, which leads to a coupling strength (λ=0.057) that is nearly an order of magnitude smaller than those of common metals. The abnormally weak electron-phonon coupling in PdCoO2 results from a low electronic density of states at the Fermi level, as well as the large and strongly facetted Fermi surface with suppressed Umklapp electron-phonon matrix elements. We anticipate that our work will inform the design of unconventional metals with superior transport properties.