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Free keywords:
Carrier concentration, Electronic structure, Hall mobility, Hole mobility, Indium, Indium compounds, Rietveld refinement, Thermal conductivity, Thermoelectricity, Effective electrons, Electronic structure calculations, Electronic transport properties, Powder X ray diffraction, Solubility limits, Tetragonal phasis, Thermoelectric figure of merit, Thermoelectric performance, Selenium compounds
Abstract:
A structural and thermoelectric study of the polycrystalline Se- and Te-substituted In2.67S4thiospinels was performed. The obtained In2.67S4−xSex(0 ≤x≤ 0.5) and In2.67S4−yTey(0 ≤y≤ 0.15) samples were single phase and the solubility limits of Se and Te were not reached. A comprehensive phase analysis based on powder X-ray diffraction and Raman spectroscopy, as well as Rietveld refinements, confirmed that Se/Te-incorporation into the structure of binary β-In2.67S4(x= 0) favors the formation of the cubic α-modification forx> 0.15 andy≥ 0.05. Moreover, both cubic and tetragonal phases were shown to coexist in the In2.67S3.9Se0.1specimen. The Se/Te-for-S substitution strongly influenced electronic transport properties, leading to an increase of the charge carrier concentration and thus, a reduction of the electrical resistivity and Seebeck coefficient. A decrease of charge carrier mobility, observed previously upon the stabilization of the α-phase, was partially counterbalanced by a reduction of effective electron mass, as revealed by the electronic structure calculations. This resulted in the enhancement of the power factor PF > 10−4W m−1K−2above RT for In2.67S3.9Se0.1and In2.67S3.5Se0.5thiospinels in comparison to pristine In2.67S4. Combination of such an effect with the decreased thermal conductivity (i.e., < 1.5 W m−1K−1above RT) led to the improvement of the thermoelectric figure of merit by factor of 2.5 in In2.67S3.5Se0.5 © The Royal Society of Chemistry 2021.