Quasiparticle to local moment crossover in bad metals

Abstract

Non-Fermi-liquid charge transport in the vicinity of electronic instabilities has been intensely studied for decades. Deviations from FL=0+AT2 in bad and strange metals are commonly ascribed to a breakdown of Landau's quasiparticle (QP) concept. Yet, it remains unclear what mechanism drives the temperature dependence of (T) beyond FL. Here, we examine the bad metal upon approaching the Mott metal-insulator transition via chemical pressure in -[(BEDT-STF)x(BEDT-TTF)1-x] 2 Cu2 (CN)3. Through nuclear magnetic resonance (NMR) and transport experiments on the same single crystals, we directly link the onset of deviations from Korringa law (T1T)-1 = const. with the rise of (T) beyond FL. From the NMR relaxation rate, we can identify the gradual crossover between the QP-dominated regime at low T to predominant local moments at higher T. By comparing our experimental findings with dynamical mean-field theory calculations, which accurately reproduce the transport data, we reveal how this crossover is reflected in T-dependent changes of the QP spectrum. Near the Mott insulator, where d/dT<0 at high T, an Einstein-relation analysis shows that bad-metal behavior with d/dT>0 is driven by the temperature dependence of the electronic compressibility rather than the diffusion constant.