Strongly correlated properties of the thermoelectric cobalt oxide Ca3Co4O9

TL;DR

This study investigates the complex temperature-dependent electronic transport and thermodynamic properties of Ca3Co4O9, revealing multiple regimes of correlated behavior, effective mass enhancement, and pressure effects on quasiparticle coherence.

Contribution

It provides detailed experimental characterization of the distinct transport regimes and their relation to quasiparticle coherence in Ca3Co4O9, highlighting the role of strong correlations.

Findings

Four transport regimes identified with temperature

Large electronic effective mass indicated by specific heat

Pressure decreases Fermi liquid coefficient A

Abstract

We have performed both in-plane resistivity, Hall effect and specific heat measurements on the thermoelectric cobalt oxide Ca$_{3}$Co$_{4}$O$_{9}$. Four distinct transport regimes are found as a function of temperature, corresponding to a low temperature insulating one up to $T_{min}\approx $63 K, a strongly correlated Fermi liquid up to $T^*\approx $140 K, with $\rho=\rho_0+AT^2$ and $A\approx 3.63$ $10^{-2} \mu \Omega cm/K^{2}$, followed by an incoherent metal with $k_Fl\leq 1$ and a high temperature insulator above T$^{**}\approx $510 K . Specific heat Sommerfeld coefficient $\gamma = 93$ mJ/(mol.K$^{2}$) confirms a rather large value of the electronic effective mass and fulfils the Kadowaki-Woods ratio $A/\gamma^2 \approx 0.45$ 10$^{-5}$ $\mu \Omega cm.K^2/(mJ^2mol^{-2})$. Resistivity measurements under pressure reveal a decrease of the Fermi liquid transport coefficient A with an increase of $T^*$ as a function of pressure while the product $A(T^*)^2/a$ remains constant and of order $h/e^2$. Both thermodynamic and transport properties suggest a strong renormalization of the quasiparticles coherence scale of order $T^*$ that seems to govern also thermopower.