Litcius/Paper detail

Effect of microstructure on thermoelectric conversion efficiency in metastable δ-phase AgSbTe2

Jae-Ki Lee, Byungki Ryu, Sungjin Park, Ji Hee Son, Jongho Park, Jeongin Jang, Min‐Wook Oh, Su-Dong Park

2021Acta Materialia40 citationsDOIOpen Access PDF

Abstract

Herein, the effect of AgSbTe2 microstructure on the thermoelectric conversion efficiency of an AgSbTe2-based alloy was studied. The as-sintered sample exhibited material separation into a multiphase mixture of cubic Sb-rich AgSbTe2 (Ag21Sb28Te51), monoclinic Ag2Te with an inhomogeneous distribution, and an Sb-rich zone. The samples were subjected to heat treatment for 24 h at 523, 573, and 673 K. The results indicated that AgSbTe2 was metastable against Ag2Te and Sb2Te3 at 573 K. The accelerated kinetics induced the separation of AgSbTe2 into less-Sb-rich δ’-AgSbTe2 and Sb2Te3 with sub-µm sizes. The observations also revealed that AgSbTe2 was stable against Ag2Te and Sb2Te3 at 673 K. Micrometer-scale Ag2Te precipitates and rhombohedral Sb2Te3 phases were dissolved in the main matrix. Furthermore, single-phase δ-AgSbTe2 was stabilized with nanoscale precipitates of Ag2Te and Sb-rich nanodots. The thermoelectric transport properties of the heat-treated samples were investigated. The results indicated that the thermoelectric performance of the single-phase metastable structure with nanoscale precipitates was superior to that of the multiphase structure. Multiphase AgSbTe2 exhibited a low thermal conductivity; however, the effective Seebeck coefficient was balanced by the presence of multiple phases. This resulted in a low thermoelectric power factor. Metastable single-phase AgSbTe2, with Ag2Te and Sb-rich nanodots, exhibited a high Seebeck coefficient with a slightly low p-type conductivity. This resulted in a high thermoelectric power factor, and the presence of nanoscale precipitates lowered the thermal conductivity. It was concluded that the thermoelectric performance of metastable single-phase δ-AgSbTe2 was superior to that of multiphase AgSbTe2.

Topics & Concepts

Materials scienceMicrostructureMetastabilityThermoelectric effectPhase (matter)Thermoelectric materialsEngineering physicsMetallurgyComposite materialThermodynamicsThermal conductivityEngineeringQuantum mechanicsPhysicsOrganic chemistryChemistryAdvanced Thermoelectric Materials and DevicesChalcogenide Semiconductor Thin FilmsAdvanced Semiconductor Detectors and Materials
Effect of microstructure on thermoelectric conversion efficiency in metastable δ-phase AgSbTe2 | Litcius