Influence of Y³⁺ doping on the high-temperature transport mechanism and thermoelectric response of misfit-layered Ca₃Co ₄O₉

The high-temperature transport and thermoelectric characteristics of Ca_3-xYxCo₄O₉ (x = 0-0.75) series were studied up to 1000 K. The results reveal that the substitution of Y³⁺ for Ca²⁺ not only increases resistivity but also gradually alters the transport mechanism. The localization of carriers narrows bandwidth, which induces the evolution of the system from metal to variable-range hopping semiconductor and then to thermally activated semiconductor. The increasing thermopower with doping originates from the reduction of carrier concentration along with enhanced electronic correlations. Thermoelectric figure of merit ZT of Ca_3-xYxCo₄O₉ system is improved by Y doping. However, the optimal thermoelectric performance is found to only exist at the critical doping level where doping-induced metal- semiconductor transition occurs. This result suggests an intrinsic correlation between transport mechanism and thermoelectric response in this system.