Electrical Transport Properties Driven by Unique Bonding Configuration in γ-GeSe

Jeongsu Jang; Joonho Kim; Dongchul Sung; Jong Hyuk Kim; Joong Eon Jung; Sol Lee; Jinsub Park; Chaewoon Lee; Heesun Bae; Seongil Im; Kibog Park; Young Jai Choi; Suklyun Hong; Kwanpyo Kim

doi:10.1021/acs.nanolett.2c04425

Electrical Transport Properties Driven by Unique Bonding Configuration in γ-GeSe

Jeongsu Jang, Joonho Kim, Dongchul Sung, Jong Hyuk Kim, Joong Eon Jung, Sol Lee, Jinsub Park, Chaewoon Lee, Heesun Bae, Seongil Im, Kibog Park, Young Jai Choi, Suklyun Hong, Kwanpyo Kim

Department of Physics

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

Group IV monochalcogenides have recently shown great potential for their thermoelectric, ferroelectric, and other intriguing properties. The electrical properties of group IV monochalcogenides exhibit a strong dependence on the chalcogen type. For example, GeTe exhibits high doping concentration, whereas S/Se-based chalcogenides are semiconductors with sizable bandgaps. Here, we investigate the electrical and thermoelectric properties of γ-GeSe, a recently identified polymorph of GeSe. γ-GeSe exhibits high electrical conductivity (∼10⁶ S/m) and a relatively low Seebeck coefficient (9.4 μV/K at room temperature) owing to its high p-doping level (5 × 10²¹ cm^-3), which is in stark contrast to other known GeSe polymorphs. Elemental analysis and first-principles calculations confirm that the abundant formation of Ge vacancies leads to the high p-doping concentration. The magnetoresistance measurements also reveal weak antilocalization because of spin-orbit coupling in the crystal. Our results demonstrate that γ-GeSe is a unique polymorph in which the modified local bonding configuration leads to substantially different physical properties.

Original language	English
Pages (from-to)	3144-3151
Number of pages	8
Journal	Nano letters
Volume	23
Issue number	8
DOIs	https://doi.org/10.1021/acs.nanolett.2c04425
Publication status	Published - 2023 Apr 26

Bibliographical note

Publisher Copyright:
© 2023 American Chemical Society

All Science Journal Classification (ASJC) codes

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/acs.nanolett.2c04425

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title = "Electrical Transport Properties Driven by Unique Bonding Configuration in γ-GeSe",

abstract = "Group IV monochalcogenides have recently shown great potential for their thermoelectric, ferroelectric, and other intriguing properties. The electrical properties of group IV monochalcogenides exhibit a strong dependence on the chalcogen type. For example, GeTe exhibits high doping concentration, whereas S/Se-based chalcogenides are semiconductors with sizable bandgaps. Here, we investigate the electrical and thermoelectric properties of γ-GeSe, a recently identified polymorph of GeSe. γ-GeSe exhibits high electrical conductivity (∼106 S/m) and a relatively low Seebeck coefficient (9.4 μV/K at room temperature) owing to its high p-doping level (5 × 1021 cm-3), which is in stark contrast to other known GeSe polymorphs. Elemental analysis and first-principles calculations confirm that the abundant formation of Ge vacancies leads to the high p-doping concentration. The magnetoresistance measurements also reveal weak antilocalization because of spin-orbit coupling in the crystal. Our results demonstrate that γ-GeSe is a unique polymorph in which the modified local bonding configuration leads to substantially different physical properties.",

keywords = "Hall measurement, Seebeck coefficient, group IV monochalcogenides, hexagonal GeSe, spin−orbit coupling, thermoelectric",

author = "Jeongsu Jang and Joonho Kim and Dongchul Sung and Kim, {Jong Hyuk} and Jung, {Joong Eon} and Sol Lee and Jinsub Park and Chaewoon Lee and Heesun Bae and Seongil Im and Kibog Park and Choi, {Young Jai} and Suklyun Hong and Kwanpyo Kim",

note = "Publisher Copyright: {\textcopyright} 2023 American Chemical Society",

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doi = "10.1021/acs.nanolett.2c04425",

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T1 - Electrical Transport Properties Driven by Unique Bonding Configuration in γ-GeSe

AU - Jang, Jeongsu

AU - Kim, Joonho

AU - Sung, Dongchul

AU - Kim, Jong Hyuk

AU - Jung, Joong Eon

AU - Lee, Sol

AU - Park, Jinsub

AU - Lee, Chaewoon

AU - Bae, Heesun

AU - Im, Seongil

AU - Park, Kibog

AU - Choi, Young Jai

AU - Hong, Suklyun

AU - Kim, Kwanpyo

PY - 2023/4/26

Y1 - 2023/4/26

N2 - Group IV monochalcogenides have recently shown great potential for their thermoelectric, ferroelectric, and other intriguing properties. The electrical properties of group IV monochalcogenides exhibit a strong dependence on the chalcogen type. For example, GeTe exhibits high doping concentration, whereas S/Se-based chalcogenides are semiconductors with sizable bandgaps. Here, we investigate the electrical and thermoelectric properties of γ-GeSe, a recently identified polymorph of GeSe. γ-GeSe exhibits high electrical conductivity (∼106 S/m) and a relatively low Seebeck coefficient (9.4 μV/K at room temperature) owing to its high p-doping level (5 × 1021 cm-3), which is in stark contrast to other known GeSe polymorphs. Elemental analysis and first-principles calculations confirm that the abundant formation of Ge vacancies leads to the high p-doping concentration. The magnetoresistance measurements also reveal weak antilocalization because of spin-orbit coupling in the crystal. Our results demonstrate that γ-GeSe is a unique polymorph in which the modified local bonding configuration leads to substantially different physical properties.

AB - Group IV monochalcogenides have recently shown great potential for their thermoelectric, ferroelectric, and other intriguing properties. The electrical properties of group IV monochalcogenides exhibit a strong dependence on the chalcogen type. For example, GeTe exhibits high doping concentration, whereas S/Se-based chalcogenides are semiconductors with sizable bandgaps. Here, we investigate the electrical and thermoelectric properties of γ-GeSe, a recently identified polymorph of GeSe. γ-GeSe exhibits high electrical conductivity (∼106 S/m) and a relatively low Seebeck coefficient (9.4 μV/K at room temperature) owing to its high p-doping level (5 × 1021 cm-3), which is in stark contrast to other known GeSe polymorphs. Elemental analysis and first-principles calculations confirm that the abundant formation of Ge vacancies leads to the high p-doping concentration. The magnetoresistance measurements also reveal weak antilocalization because of spin-orbit coupling in the crystal. Our results demonstrate that γ-GeSe is a unique polymorph in which the modified local bonding configuration leads to substantially different physical properties.

KW - Hall measurement

KW - Seebeck coefficient

KW - group IV monochalcogenides

KW - hexagonal GeSe

KW - spin−orbit coupling

KW - thermoelectric

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Electrical Transport Properties Driven by Unique Bonding Configuration in γ-GeSe

Abstract

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