Breaking the Trade-Off Between Mobility and On–Off Ratio in Oxide Transistors

Yu Cheng Chang; Sung Tsun Wang; Yung Ting Lee; Ching Shuan Huang; Chu Hsiu Hsu; Tzu Ting Weng; Chang Chang Huang; Chien Wei Chen; Tsung Te Chou; Chan Yuen Chang; Wei Yen Woon; Chun Liang Lin; Jack Yuan Chen Sun; Der Hsien Lien

doi:10.1002/adma.202413212

Breaking the Trade-Off Between Mobility and On–Off Ratio in Oxide Transistors

Yu Cheng Chang, Sung Tsun Wang, Yung Ting Lee, Ching Shuan Huang, Chu Hsiu Hsu, Tzu Ting Weng, Chang Chang Huang, Chien Wei Chen, Tsung Te Chou, Chan Yuen Chang, Wei Yen Woon, Chun Liang Lin, Jack Yuan Chen Sun, Der Hsien Lien^*

^*此作品的通信作者

研究成果: Article › 同行評審

7 引文斯高帕斯（Scopus）

摘要

Amorphous oxide semiconductors (AOS) are pivotal for next-generation electronics due to their high electron mobility and excellent optical properties. However, In₂O₃, a key material in this family, encounters significant challenges in balancing high mobility and effective switching as its thickness is scaled down to nanometer dimensions. The high electron density in ultra-thin In₂O₃ hinders its ability to turn off effectively, leading to a critical trade-off between mobility and the on-current (I_on)/off-current (I_off) ratio. This study introduces a mild CF₄ plasma doping technique that effectively reduces electron density in 10 nm In₂O₃ at a low processing temperature of 70 °C, achieving a high mobility of 104 cm² V⁻¹ s⁻¹ and an I_on/I_off ratio exceeding 10⁸. A subsequent low-temperature post-annealing further improves the critical reliability and stability of CF₄-doped In₂O₃ without raising the thermal budget, making this technique suitable for monolithic three-dimensional (3D) integration. Additionally, its application is demonstrated in In₂O₃ depletion-load inverters, highlighting its potential for advanced logic circuits and broader electronic and optoelectronic applications.

原文	English
文章編號	2413212
期刊	Advanced Materials
卷	37
發行號	5
DOIs	https://doi.org/10.1002/adma.202413212
出版狀態	Published - 5 2月 2025

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title = "Breaking the Trade-Off Between Mobility and On–Off Ratio in Oxide Transistors",

abstract = "Amorphous oxide semiconductors (AOS) are pivotal for next-generation electronics due to their high electron mobility and excellent optical properties. However, In2O3, a key material in this family, encounters significant challenges in balancing high mobility and effective switching as its thickness is scaled down to nanometer dimensions. The high electron density in ultra-thin In2O3 hinders its ability to turn off effectively, leading to a critical trade-off between mobility and the on-current (Ion)/off-current (Ioff) ratio. This study introduces a mild CF4 plasma doping technique that effectively reduces electron density in 10 nm In2O3 at a low processing temperature of 70 °C, achieving a high mobility of 104 cm2 V⁻¹ s⁻¹ and an Ion/Ioff ratio exceeding 10⁸. A subsequent low-temperature post-annealing further improves the critical reliability and stability of CF4-doped In2O3 without raising the thermal budget, making this technique suitable for monolithic three-dimensional (3D) integration. Additionally, its application is demonstrated in In2O3 depletion-load inverters, highlighting its potential for advanced logic circuits and broader electronic and optoelectronic applications.",

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author = "Chang, \{Yu Cheng\} and Wang, \{Sung Tsun\} and Lee, \{Yung Ting\} and Huang, \{Ching Shuan\} and Hsu, \{Chu Hsiu\} and Weng, \{Tzu Ting\} and Huang, \{Chang Chang\} and Chen, \{Chien Wei\} and Chou, \{Tsung Te\} and Chang, \{Chan Yuen\} and Woon, \{Wei Yen\} and Lin, \{Chun Liang\} and Sun, \{Jack Yuan Chen\} and Lien, \{Der Hsien\}",

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AU - Chang, Yu Cheng

AU - Wang, Sung Tsun

AU - Lee, Yung Ting

AU - Huang, Ching Shuan

AU - Hsu, Chu Hsiu

AU - Weng, Tzu Ting

AU - Huang, Chang Chang

AU - Chen, Chien Wei

AU - Chou, Tsung Te

AU - Chang, Chan Yuen

AU - Woon, Wei Yen

AU - Lin, Chun Liang

AU - Sun, Jack Yuan Chen

AU - Lien, Der Hsien

PY - 2025/2/5

Y1 - 2025/2/5

N2 - Amorphous oxide semiconductors (AOS) are pivotal for next-generation electronics due to their high electron mobility and excellent optical properties. However, In2O3, a key material in this family, encounters significant challenges in balancing high mobility and effective switching as its thickness is scaled down to nanometer dimensions. The high electron density in ultra-thin In2O3 hinders its ability to turn off effectively, leading to a critical trade-off between mobility and the on-current (Ion)/off-current (Ioff) ratio. This study introduces a mild CF4 plasma doping technique that effectively reduces electron density in 10 nm In2O3 at a low processing temperature of 70 °C, achieving a high mobility of 104 cm2 V⁻¹ s⁻¹ and an Ion/Ioff ratio exceeding 10⁸. A subsequent low-temperature post-annealing further improves the critical reliability and stability of CF4-doped In2O3 without raising the thermal budget, making this technique suitable for monolithic three-dimensional (3D) integration. Additionally, its application is demonstrated in In2O3 depletion-load inverters, highlighting its potential for advanced logic circuits and broader electronic and optoelectronic applications.

AB - Amorphous oxide semiconductors (AOS) are pivotal for next-generation electronics due to their high electron mobility and excellent optical properties. However, In2O3, a key material in this family, encounters significant challenges in balancing high mobility and effective switching as its thickness is scaled down to nanometer dimensions. The high electron density in ultra-thin In2O3 hinders its ability to turn off effectively, leading to a critical trade-off between mobility and the on-current (Ion)/off-current (Ioff) ratio. This study introduces a mild CF4 plasma doping technique that effectively reduces electron density in 10 nm In2O3 at a low processing temperature of 70 °C, achieving a high mobility of 104 cm2 V⁻¹ s⁻¹ and an Ion/Ioff ratio exceeding 10⁸. A subsequent low-temperature post-annealing further improves the critical reliability and stability of CF4-doped In2O3 without raising the thermal budget, making this technique suitable for monolithic three-dimensional (3D) integration. Additionally, its application is demonstrated in In2O3 depletion-load inverters, highlighting its potential for advanced logic circuits and broader electronic and optoelectronic applications.

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KW - amorphous oxide semiconductors

KW - electron degeneracy suppression

KW - high mobility

KW - monolithic 3D integration

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Breaking the Trade-Off Between Mobility and On–Off Ratio in Oxide Transistors

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