High Mobilities in Layered InSe Transistors with Indium-Encapsulation-Induced Surface Charge Doping

Mengjiao Li; Che Yi Lin; Shih Hsien Yang; Yuan Ming Chang; Jen Kuei Chang; Feng Shou Yang; Chaorong Zhong; Wen-Bin Jian; Chen Hsin Lien; Ching Hwa Ho; Heng Jui Liu; Rong Huang; Wenwu Li; Yen Fu Lin; Junhao Chu

doi:10.1002/adma.201803690

High Mobilities in Layered InSe Transistors with Indium-Encapsulation-Induced Surface Charge Doping

Mengjiao Li, Che Yi Lin, Shih Hsien Yang, Yuan Ming Chang, Jen Kuei Chang, Feng Shou Yang, Chaorong Zhong, Wen-Bin Jian, Chen Hsin Lien, Ching Hwa Ho, Heng Jui Liu, Rong Huang, Wenwu Li^*, Yen Fu Lin, Junhao Chu

^*Corresponding author for this work

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

131 Scopus citations

Abstract

Tunability and stability in the electrical properties of 2D semiconductors pave the way for their practical applications in logic devices. A robust layered indium selenide (InSe) field-effect transistor (FET) with superior controlled stability is demonstrated by depositing an indium (In) doping layer. The optimized InSe FETs deliver an unprecedented high electron mobility up to 3700 cm² V⁻¹ s⁻¹ at room temperature, which can be retained with 60% after 1 month. Further insight into the evolution of the position of the Fermi level and the microscopic device structure with different In thicknesses demonstrates an enhanced electron-doping behavior at the In/InSe interface. Furthermore, the contact resistance is also improved through the In insertion between InSe and Au electrodes, which coincides with the analysis of the low-frequency noise. The carrier fluctuation is attributed to the dominance of the phonon scattering events, which agrees with the observation of the temperature-dependent mobility. Finally, the flexible functionalities of the logic-circuit applications, for instance, inverter and not-and (NAND)/not-or (NOR) gates, are determined with these surface-doping InSe FETs, which establish a paradigm for 2D-based materials to overcome the bottleneck in the development of electronic devices.

Original language	English
Article number	1803690
Pages (from-to)	1-10
Number of pages	10
Journal	Advanced Materials
Volume	30
Issue number	44
DOIs	https://doi.org/10.1002/adma.201803690
State	Published - 2 Nov 2018

Keywords

2D electronics
InSe transistors
logic circuits
low-frequency noise
surface charge transfer doping

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10.1002/adma.201803690

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Li, M., Lin, C. Y., Yang, S. H., Chang, Y. M., Chang, J. K., Yang, F. S., Zhong, C., Jian, W.-B., Lien, C. H., Ho, C. H., Liu, H. J., Huang, R., Li, W., Lin, Y. F., & Chu, J. (2018). High Mobilities in Layered InSe Transistors with Indium-Encapsulation-Induced Surface Charge Doping. Advanced Materials, 30(44), 1-10. Article 1803690. https://doi.org/10.1002/adma.201803690

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title = "High Mobilities in Layered InSe Transistors with Indium-Encapsulation-Induced Surface Charge Doping",

abstract = "Tunability and stability in the electrical properties of 2D semiconductors pave the way for their practical applications in logic devices. A robust layered indium selenide (InSe) field-effect transistor (FET) with superior controlled stability is demonstrated by depositing an indium (In) doping layer. The optimized InSe FETs deliver an unprecedented high electron mobility up to 3700 cm2 V−1 s−1 at room temperature, which can be retained with 60% after 1 month. Further insight into the evolution of the position of the Fermi level and the microscopic device structure with different In thicknesses demonstrates an enhanced electron-doping behavior at the In/InSe interface. Furthermore, the contact resistance is also improved through the In insertion between InSe and Au electrodes, which coincides with the analysis of the low-frequency noise. The carrier fluctuation is attributed to the dominance of the phonon scattering events, which agrees with the observation of the temperature-dependent mobility. Finally, the flexible functionalities of the logic-circuit applications, for instance, inverter and not-and (NAND)/not-or (NOR) gates, are determined with these surface-doping InSe FETs, which establish a paradigm for 2D-based materials to overcome the bottleneck in the development of electronic devices.",

keywords = "2D electronics, InSe transistors, logic circuits, low-frequency noise, surface charge transfer doping",

author = "Mengjiao Li and Lin, {Che Yi} and Yang, {Shih Hsien} and Chang, {Yuan Ming} and Chang, {Jen Kuei} and Yang, {Feng Shou} and Chaorong Zhong and Wen-Bin Jian and Lien, {Chen Hsin} and Ho, {Ching Hwa} and Liu, {Heng Jui} and Rong Huang and Wenwu Li and Lin, {Yen Fu} and Junhao Chu",

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AU - Yang, Shih Hsien

AU - Chang, Yuan Ming

AU - Chang, Jen Kuei

AU - Yang, Feng Shou

AU - Zhong, Chaorong

AU - Jian, Wen-Bin

AU - Lien, Chen Hsin

AU - Ho, Ching Hwa

AU - Liu, Heng Jui

AU - Huang, Rong

AU - Li, Wenwu

AU - Lin, Yen Fu

AU - Chu, Junhao

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N2 - Tunability and stability in the electrical properties of 2D semiconductors pave the way for their practical applications in logic devices. A robust layered indium selenide (InSe) field-effect transistor (FET) with superior controlled stability is demonstrated by depositing an indium (In) doping layer. The optimized InSe FETs deliver an unprecedented high electron mobility up to 3700 cm2 V−1 s−1 at room temperature, which can be retained with 60% after 1 month. Further insight into the evolution of the position of the Fermi level and the microscopic device structure with different In thicknesses demonstrates an enhanced electron-doping behavior at the In/InSe interface. Furthermore, the contact resistance is also improved through the In insertion between InSe and Au electrodes, which coincides with the analysis of the low-frequency noise. The carrier fluctuation is attributed to the dominance of the phonon scattering events, which agrees with the observation of the temperature-dependent mobility. Finally, the flexible functionalities of the logic-circuit applications, for instance, inverter and not-and (NAND)/not-or (NOR) gates, are determined with these surface-doping InSe FETs, which establish a paradigm for 2D-based materials to overcome the bottleneck in the development of electronic devices.

AB - Tunability and stability in the electrical properties of 2D semiconductors pave the way for their practical applications in logic devices. A robust layered indium selenide (InSe) field-effect transistor (FET) with superior controlled stability is demonstrated by depositing an indium (In) doping layer. The optimized InSe FETs deliver an unprecedented high electron mobility up to 3700 cm2 V−1 s−1 at room temperature, which can be retained with 60% after 1 month. Further insight into the evolution of the position of the Fermi level and the microscopic device structure with different In thicknesses demonstrates an enhanced electron-doping behavior at the In/InSe interface. Furthermore, the contact resistance is also improved through the In insertion between InSe and Au electrodes, which coincides with the analysis of the low-frequency noise. The carrier fluctuation is attributed to the dominance of the phonon scattering events, which agrees with the observation of the temperature-dependent mobility. Finally, the flexible functionalities of the logic-circuit applications, for instance, inverter and not-and (NAND)/not-or (NOR) gates, are determined with these surface-doping InSe FETs, which establish a paradigm for 2D-based materials to overcome the bottleneck in the development of electronic devices.

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High Mobilities in Layered InSe Transistors with Indium-Encapsulation-Induced Surface Charge Doping

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