Prominent electron-hole asymmetry in thermoelectric transport of LaCoO3

Abstract

We have measured the electrical resistivity and the thermopower of the electron-doped perovskite cobaltites LaCo1-yTeyO3. In contrast to the hole-doped systems such as metallic ferromagnets La1-xMxCoO3 (M = Ca, Sr, Ba), the electron-doped samples show an insulating behavior even in a heavily doped range due to a spin-state blockade mechanism that an electron hopping from high-spin Co2+ to low-spin Co3+ site is energetically suppressed. We find that, despite the electron doping, the thermopower shows relatively large positive values above y=0.05, strikingly distinct from the hole-doped case where it comes close to zero with doping. This prominent electron-hole asymmetry seen in the thermopower originates from a bipolar conduction which consists of a slight amount of mobile holes and the main immobile electrons, demonstrating an impact of spin-state blockade on thermoelectric transport.