Enhanced thermoelectric performance of SnSe by controlled vacancy population

Ji-Eun Lee; Kyoo Kim; Van Quang Nguyen; Jinwoong Hwang; Jonathan D. Denlinger; Byung Il Min; Sunglae Cho; Hyejin Ryu; Choongyu Hwang; Sung-Kwan Mo

doi:10.1186/s40580-023-00381-7

Nano Convergence (Jul 2023)

Enhanced thermoelectric performance of SnSe by controlled vacancy population

Ji-Eun Lee,
Kyoo Kim,
Van Quang Nguyen,
Jinwoong Hwang,
Jonathan D. Denlinger,
Byung Il Min,
Sunglae Cho,
Hyejin Ryu,
Choongyu Hwang,
Sung-Kwan Mo

Affiliations

Ji-Eun Lee: Advanced Light Source, Lawrence Berkeley National Laboratory
Kyoo Kim: Max Planck-POSTECH/Hsinchu Center for Complex Phase Materials, Max Plank POSTECH/Korea Research Initiative (MPK)
Van Quang Nguyen: Department of Physics and Energy Harvest-Storage Research Center, University of Ulsan
Jinwoong Hwang: Advanced Light Source, Lawrence Berkeley National Laboratory
Jonathan D. Denlinger: Advanced Light Source, Lawrence Berkeley National Laboratory
Byung Il Min: Department of Physics, Pohang University of Science and Technology (POSTECH)
Sunglae Cho: Department of Physics and Energy Harvest-Storage Research Center, University of Ulsan
Hyejin Ryu: Advanced Light Source, Lawrence Berkeley National Laboratory
Choongyu Hwang: Department of Physics, Pusan National University
Sung-Kwan Mo: Advanced Light Source, Lawrence Berkeley National Laboratory

DOI: https://doi.org/10.1186/s40580-023-00381-7
Journal volume & issue: Vol. 10, no. 1
pp. 1 – 6

Abstract

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Abstract The thermoelectric performance of SnSe strongly depends on its low-energy electron band structure that provides high density of states in a narrow energy window due to the multi-valley valence band maximum (VBM). Angle-resolved photoemission spectroscopy measurements, in conjunction with first-principles calculations, reveal that the binding energy of the VBM of SnSe is tuned by the population of Sn vacancy, which is determined by the cooling rate during the sample growth. The VBM shift follows precisely the behavior of the thermoelectric power factor, while the effective mass is barely modified upon changing the population of Sn vacancies. These findings indicate that the low-energy electron band structure is closely correlated with the high thermoelectric performance of hole-doped SnSe, providing a viable route toward engineering the intrinsic defect-induced thermoelectric performance via the sample growth condition without an additional ex-situ process. Graphical Abstract

Published in Nano Convergence

ISSN: 2196-5404 (Online)
Publisher: SpringerOpen
Country of publisher: Germany
LCC subjects: Technology: Chemical technology: Biotechnology; Science: Physics
Website: http://www.nanoconvergencejournal.com

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