Enhancing the thermoelectric performance of Sr0.6La0.4Nb2O6-δ-based ceramics through composite effects

Abstract

Donor-doped SrNb2O6-based materials are regarded as highly promising candidates for high-temperature thermoelectric applications. The Sr0.6La0.4Nb2O6-δ/x wt% Ti (x = 1, 5, 10, 15) composite ceramics thermoelectric materials were prepared and the mechanism for enhancing their thermoelectric properties was investigated. The experimental results demonstrate that during sintering, nano-additive titanium powder undergoes oxidation to form TiO2. The inclusion of a secondary phase ultimately leads to successful reduction in electrical resistivity within the composite oxides. Due to crystal defects, complex structure and phonon scattering at grain boundaries, the samples consistently exhibit low thermal conductivity values below 3.0 W m−1K−1. Among them, the sample doped with 10 wt% Ti shows the highest PF value (470.0 μW/mK2 at 1073 K), demonstrating a significant increase in power factor of 280 % compared to Sr0.6La0.4Nb2O6 without the Ti composite. Consequently, the Sr0.6La0.4Nb2O6-δ/10 wt% Ti composite material achieved a maximum ZT value of 0.20, representing a fifty-three percent enhancement compared to the undoped sample.