Gainza, JavierSerrano-Sánchez, FedericoNemes, Norbert MarcelMartínez, José LuisFernández-Díaz, María TeresaAlonso, José Antonio2023-06-172023-06-172019-12-252075-470110.3390/met10010048https://hdl.handle.net/20.500.14352/8099Among other chalcogenide thermoelectric materials, GeTe and derivative alloys are good candidates for intermediate temperature applications, as a replacement for toxic PbTe. We have prepared pure polycrystalline GeTe by using arc-melting, and investigated its structural evolution by using neutron powder diffraction (NPD) and synchrotron X-ray diffraction (SXRD), as well as its correlation with the thermal variation of the Seebeck coefficient. Besides a significant Ge deficiency (~7% Ge vacancies), the thermal evolution of the unit-cell volume and Ge-Te bond lengths in the rhombohedral phase (space group R3m), below 700 K, show unexpected anomalies involving the abrupt Ge-Te bond lengthening accompanied by increased Te thermal displacements. Above 700 K, the sample is cubic (space group Fm-3m) and shows considerably larger displacement parameters for Ge than for Te, as a consequence of the random distribution of the lone pair lobes of Ge2+. The Seebeck coefficient, reaching 120 μV K−1 at 775 K, shows a shoulder in the 500–570 K region that can be correlated to the structural anomaly, modifying the electron-phonon scattering in this temperature range.engAtribución 3.0 Españahttps://creativecommons.org/licenses/by/3.0/es/Features of the High-Temperature Structural Evolution of GeTe Thermoelectric Probed by Neutron and Synchrotron Powder Diffractionjournal articlehttps://doi.org/10.3390/met10010048https://www.mdpi.com/2075-4701/10/1/48open accessthermoelectricsneutron powder diffractionGe deficiencystructural phase transitionElectricidadTermodinámica2202.03 Electricidad2213 Termodinámica