Computational and experimental investigation of TmAgTe2and XYZ2compounds, a new group of thermoelectric materials identified by first-principles high-throughput screening

Autor: Zhu, H, Hautier, G, Aydemir, U, Gibbs, ZM, Li, G, Bajaj, S, Pöhls, JH, Broberg, D, Chen, W, Jain, A, White, MA, Asta, M, Snyder, GJ, Persson, K, Ceder, G
Jazyk: angličtina
Rok vydání: 2015
Zdroj: Zhu, H; Hautier, G; Aydemir, U; Gibbs, ZM; Li, G; Bajaj, S; et al.(2015). Computational and experimental investigation of TmAgTe2and XYZ2compounds, a new group of thermoelectric materials identified by first-principles high-throughput screening. Journal of Materials Chemistry C, 3(40), 10554-10565. doi: 10.1039/c5tc01440a. UC Berkeley: Retrieved from: http://www.escholarship.org/uc/item/3cm695cn
DOI: 10.1039/c5tc01440a.
Popis: © The Royal Society of Chemistry 2015. A new group of thermoelectric materials, trigonal and tetragonal XYZ2(X, Y: rare earth or transition metals, Z: group VI elements), the prototype of which is TmAgTe2, is identified by means of high-throughput computational screening and experiment. Based on density functional theory calculations, this group of materials is predicted to attain high zT (i.e. ∼1.8 for p-type trigonal TmAgTe2at 600 K). Among approximately 500 chemical variants of XYZ2explored, many candidates with good stability and favorable electronic band structures (with high band degeneracy leading to high power factor) are presented. Trigonal TmAgTe2has been synthesized and exhibits an extremely low measured thermal conductivity of 0.2-0.3 W m-1K-1for T > 600 K. The zT value achieved thus far for p-type trigonal TmAgTe2is approximately 0.35, and is limited by a low hole concentration (∼1017cm-3at room temperature). Defect calculations indicate that TmAgantisite defects are very likely to form and act as hole killers. Further defect engineering to reduce such XYantisites is deemed important to optimize the zT value of the p-type TmAgTe2.
Databáze: OpenAIRE