氧气等离子体处理提升InZnO材料及TFT电学性能和稳定性研究*

doi:10.13385/j.cnki.vacuum.2023.04.05

Abstract

Abstract: Oxide thin film transistors(TFT) are the core driving components of active matrix organic light-emitting diodes, and are the key technology for developing new displays today. They have broad application prospects in flat panel displays. However, there are a large number of defect states in oxide semiconductors caused by oxygen vacancies, which destroy the performance and stability of TFT device, and become a bottleneck technical problem for its commercialization. Therefore, IZO TFT was prepared by RF-sputtering and treated with O₂ plasma to study the effects of O₂ plasma treatmert on IZO film and device performance and stability. The results show that after plasma treatment, the mobility of IZO TFT increases from 8.2cm²/（V·s） to 9.5cm²/（V·s）, the threshold voltage changes from -3.2V to -5.1V, the sub-threshold swing decreases from 0.45V/decade to 0.38V/decade, and the switch ratio changes from 2.3×10⁷ to 4.4×10⁷. Under negative light bias, the threshold voltage drift of the device reduces from 7.1V to 3.2V. The threshold voltage drift of the device decreases from 12.5V to 6.4V when aging at 100℃. O₂ plasma treatment can effectively improve the electrical performance and stability of IZO TFT.

Key words: thin film transistor, RF sputtering, O₂ plasma treatment, defect, stability

CLC Number: O539;TN386

HUANG Chuan-xin, XIN Ji-ying, TIAN Zhong-jun, WANG Meng, LÜ Kai-kai, LIANG Lan-ju, LIU Yun-yun. Improvement of the Electrical Performance and Stability of InZnO Material and TFT by Oxygen Plasma Processing[J].VACUUM, 2023, 60(4): 24-28.

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Improvement of the Electrical Performance and Stability of InZnO Material and TFT by Oxygen Plasma Processing

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