An emerging quaternary semiconductor nanoribbon with gate-tunable anisotropic conductance

Shaolong Jiang; Fuchen Hou; Shengfeng Zeng; Yubo Zhang; Erding Zhao; Yilin Sun; Liyun Zhao; Cheng Zhang; Mengyuan Jia; Jun Feng Dai; Mingyuan Huang; Qing Zhang; Xiaolong Zou; Yanfeng Zhang; Junhao Lin

doi:10.1016/j.scib.2024.07.025

An emerging quaternary semiconductor nanoribbon with gate-tunable anisotropic conductance

Shaolong Jiang, Fuchen Hou, Shengfeng Zeng, Yubo Zhang, Erding Zhao, Yilin Sun^*, Liyun Zhao, Cheng Zhang, Mengyuan Jia, Jun Feng Dai, Mingyuan Huang, Qing Zhang, Xiaolong Zou, Yanfeng Zhang, Junhao Lin

^*Corresponding author for this work

School of Integrated Circuits and Electronics

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

3 Citations (Scopus)

Abstract

Two-dimensional noble transition metal chalcogenide (NTMC) semiconductors represent compelling building blocks for fabricating flexible electronic and optoelectronic devices. While binary and ternary compounds have been reported, the existence of quaternary NTMCs with a greater elemental degree of freedom remains largely unexplored. This study presents the pioneering experimental realization of a novel semiconducting quaternary NTMC material, AuPdNaS₂, synthesized directly on Au foils through chemical vapor deposition. The ribbon-shaped morphology of the AuPdNaS₂ crystal can be finely tuned to a thickness as low as 9.2 nm. Scanning transmission electron microscopy reveals the atomic arrangement, showcasing robust anisotropic features; thus, AuPdNaS₂ exhibits distinct anisotropic phonon vibrations and electrical properties. The field-effect transistor constructed from AuPdNaS₂ crystal demonstrates a pronounced anisotropic conductance (σ_max/σ_min = 3.20) under gate voltage control. This investigation significantly expands the repertoire of NTMC materials and underscores the potential applications of AuPdNaS₂ in nano-electronic devices.

Original language	English
Pages (from-to)	3228-3236
Number of pages	9
Journal	Science Bulletin
Volume	69
Issue number	20
DOIs	https://doi.org/10.1016/j.scib.2024.07.025
Publication status	Published - 30 Oct 2024

Keywords

Anisotropic conductance
AuPdNaS
Chemical vapor deposition
Gate tenability

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10.1016/j.scib.2024.07.025

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Jiang, S., Hou, F., Zeng, S., Zhang, Y., Zhao, E., Sun, Y., Zhao, L., Zhang, C., Jia, M., Dai, J. F., Huang, M., Zhang, Q., Zou, X., Zhang, Y., & Lin, J. (2024). An emerging quaternary semiconductor nanoribbon with gate-tunable anisotropic conductance. Science Bulletin, 69(20), 3228-3236. https://doi.org/10.1016/j.scib.2024.07.025

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abstract = "Two-dimensional noble transition metal chalcogenide (NTMC) semiconductors represent compelling building blocks for fabricating flexible electronic and optoelectronic devices. While binary and ternary compounds have been reported, the existence of quaternary NTMCs with a greater elemental degree of freedom remains largely unexplored. This study presents the pioneering experimental realization of a novel semiconducting quaternary NTMC material, AuPdNaS2, synthesized directly on Au foils through chemical vapor deposition. The ribbon-shaped morphology of the AuPdNaS2 crystal can be finely tuned to a thickness as low as 9.2 nm. Scanning transmission electron microscopy reveals the atomic arrangement, showcasing robust anisotropic features; thus, AuPdNaS2 exhibits distinct anisotropic phonon vibrations and electrical properties. The field-effect transistor constructed from AuPdNaS2 crystal demonstrates a pronounced anisotropic conductance (σmax/σmin = 3.20) under gate voltage control. This investigation significantly expands the repertoire of NTMC materials and underscores the potential applications of AuPdNaS2 in nano-electronic devices.",

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author = "Shaolong Jiang and Fuchen Hou and Shengfeng Zeng and Yubo Zhang and Erding Zhao and Yilin Sun and Liyun Zhao and Cheng Zhang and Mengyuan Jia and Dai, {Jun Feng} and Mingyuan Huang and Qing Zhang and Xiaolong Zou and Yanfeng Zhang and Junhao Lin",

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AU - Sun, Yilin

AU - Zhao, Liyun

AU - Zhang, Cheng

AU - Jia, Mengyuan

AU - Dai, Jun Feng

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AU - Zhang, Qing

AU - Zou, Xiaolong

AU - Zhang, Yanfeng

AU - Lin, Junhao

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AB - Two-dimensional noble transition metal chalcogenide (NTMC) semiconductors represent compelling building blocks for fabricating flexible electronic and optoelectronic devices. While binary and ternary compounds have been reported, the existence of quaternary NTMCs with a greater elemental degree of freedom remains largely unexplored. This study presents the pioneering experimental realization of a novel semiconducting quaternary NTMC material, AuPdNaS2, synthesized directly on Au foils through chemical vapor deposition. The ribbon-shaped morphology of the AuPdNaS2 crystal can be finely tuned to a thickness as low as 9.2 nm. Scanning transmission electron microscopy reveals the atomic arrangement, showcasing robust anisotropic features; thus, AuPdNaS2 exhibits distinct anisotropic phonon vibrations and electrical properties. The field-effect transistor constructed from AuPdNaS2 crystal demonstrates a pronounced anisotropic conductance (σmax/σmin = 3.20) under gate voltage control. This investigation significantly expands the repertoire of NTMC materials and underscores the potential applications of AuPdNaS2 in nano-electronic devices.

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An emerging quaternary semiconductor nanoribbon with gate-tunable anisotropic conductance

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