Thermoelectric properties and microstructure of nanocomposite Sb-GeO2 and Sb-TiO2 thin films

This work reports on fabrication and thermoelectric properties of Sb-GeO2 and Sb-TiO2 nanocomposite thin films. The formation of nanocomposite structure includes the precipitation of Sb phase and the amorphous GeO2 or TiO2 phase. In the Sb-GeO2 nanocomposite, the formation of large rhombohedral Sb grains is observed, where monoclinic Sb are formed as intermediate phase. This contributes remarkably to the elevation of conductivity, while results in the reduction of Seebeck coefficient and power factor. Contrary, the effective inhibition of Sb crystallization caused by TiO2 leads to the smaller monoclinic and rhombohedral Sb grains with homogeneous distribution in annealed Sb-TiO2 thin film. The existence of monoclinic Sb facilitates to acquire excellent thermoelectric properties. Tiny grains within the films introduce more grain boundaries, making it possible to scatter and filter low energy carriers. This leads to high conductivity, remarkable rise of the Seebeck coefficient, and excellent power factor of 765.5 & mu;W/mK2 at 650 K. The results demonstrate that the Sb-TiO2 nanocomposite materials with high power factor can be a candidate for thermoelectric devices.

Automated summary

This work focuses on the fabrication and thermoelectric properties of Sb-GeO2 and Sb-TiO2 nanocomposite thin films. In the Sb-GeO2 nanocomposite, large rhombohedral Sb grains are formed, contributing to conductivity elevation but reducing Seebeck coefficient and power factor. In contrast, effective inhibition of Sb crystallization caused by TiO2 results in smaller and more homogeneous distribution of Sb grains in the annealed Sb-TiO2 thin film, leading to excellent thermoelectric properties.