Print Email Facebook Twitter SnSe2 결함 도입으로 인한 SnSe의 고온 열전성능 증대 메커니즘 Title SnSe2 결함 도입으로 인한 SnSe의 고온 열전성능 증대 메커니즘 Author JunSu, Kim (The University of Seoul) Seong-Mee, Hwang (The University of Seoul) Hyunjin, Park (The University of Seoul) Tang, Y. (TU Delft Aerospace Structures & Computational Mechanics) Won-Seon, Seo (Yonsei University) Chae Woo, Ryu (Hongik University) Heesun, Yang (Hongik University) Weon Ho, Shin (Kwangwoon University) Hyun-Sik, Kim (The University of Seoul) Date 2023 Abstract SnSe is a promising thermoelectric material due to its low toxicity, low thermal conductivity, and multiple valence band structures, which are ideal for high electronic transport properties. The multiple valence band structure has attracted many attempts to engineer the carrier concentration of the SnSe via doping, to place its fermi level at a position where the maximum number of valence bands can participate in the electronic transport. Up until now, ~5 × 1019 cm-3 was the highest carrier concentration achieved in SnSe via doping. Recently, introducing SnSe2 into SnSe was found to effectively increase the carrier concentration as high as ~6.5 × 1019 cm-3 (at 300 K) due to the generated Sn vacancies. This high carrier concentration at 300 K, combined with the reduction in lattice thermal conductivity due to SnSe2 micro-domains formed within the SnSe lattice, improved the thermoelectric performance (zT) of SnSe – xSnSe2 as high as ~2.2 at 773 K. Here, we analyzed the changes in the electronic band parameters of SnSe as a function of temperature with varying SnSe2 content using the Single Parabolic Band (SPB) model. According to the SPB model, the calculated density-of-states effective mass and the fermi level are changed with temperature in such a way that the Hall carrier concentration (nH) of the SnSe – xSnSe2 samples at 773 K coincides with the optimum nH where the theoretically maximum zT is predicted. To optimize the nH at high temperatures for the highest zT, it is essential to tune the 300 K nH and the rate of nH change with increasing temperature via doping. Subject Carrier concentrationHigh-temperature zTPower factorSingle Parabolic Band modelSnSe To reference this document use: http://resolver.tudelft.nl/uuid:7467a69b-b18d-47c0-81e7-2061a943128e DOI https://doi.org/10.3365/KJMM.2023.61.11.857 Embargo date 2024-03-11 ISSN 1738-8228 Source Journal of Korean Institute of Metals and Materials, 61 (11), 857-866 Part of collection Institutional Repository Document type journal article Rights © 2023 Kim JunSu, Hwang Seong-Mee, Park Hyunjin, Y. Tang, Seo Won-Seon, Ryu Chae Woo, Yang Heesun, Shin Weon Ho, Kim Hyun-Sik Files PDF kjmm_2023_61_11_857.pdf 1.99 MB Close viewer /islandora/object/uuid:7467a69b-b18d-47c0-81e7-2061a943128e/datastream/OBJ/view