Theoretical and experimental search for ZnSb based thermoelectric materials

TL;DR

This study combines theoretical calculations and experimental synthesis to explore doping effects in ZnSb-based thermoelectric materials, identifying potential for improved p-type and n-type conductivity through specific dopants.

Contribution

It introduces a combined theoretical and experimental approach to doping ZnSb with Na, K, and B, revealing their effects on electronic and thermoelectric properties.

Findings

Na and K doping slightly improve p-type conductivity

B doping induces n-type behavior in ZnSb

B0.01Zn0.99Sb was successfully synthesized and characterized

Abstract

We report a combined theoretical and experimental search for thermoelectric materials based on semiconducting zinc antimony. Influence of three new doping elements (sodium, potassium and boron) on the electronic properties is investigated as well as the carrier concentration and temperature dependence of the thermoelectric coefficients obtained through density-functional calculations and Boltzmann transport theory. Distortion of the electron arrangement caused by the doping elements is displayed as a deformation charge density around the atoms. Based on the band structures, the density of states and the transport properties, we find that the presence of Na and K in the ZnSb matrix leads to a slightly improved p-type conductivity while the B substitution leads to a n-type doping. Due to the stronger need of obtaining a n-type ZnSb based material, the B0.01Zn0.99Sb structure has been transferred to the laboratory in order to be synthesized by direct melting. The sample is investigated by X-ray diffraction and Scanning Electron Microscopy.