P‐2: Investigation of high mobility crystalline IGO TFT with top‐gate structure for LCD display application

P‐2: Investigation of high mobility crystalline IGO TFT with top‐gate structure for LCD display application

The present paper reports the study of electrical characteristics and bias temperature stress (BT) stability of crystalline Indium‐Gallium oxide (IGO) dual‐gate thin film transistor (TFT) with top‐gate structure. TFT with normalized Ion over 100εA and PBTS/NBTIS of 0.35/‐2.85V was successfully fabri...

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Veröffentlicht in:SID International Symposium Digest of technical papers 2024-06, Vol.55 (1), p.1371-1374
Hauptverfasser: Haijiao, Qian, Xianjie, Shao, Yanlong, Li, Zhilei, Sun, Youwei, Zhang, Yujie, Lv, Honggang, Gu, Zhangtao, Wang
Format: Artikel
Sprache:eng
Schlagworte:
Crystal structure
Crystalline metal oxide
Crystallinity
Deposition
Gallium oxides
High mobility
High stability
Indium oxides
Partial pressure
Preferred orientation
Semiconductor devices
Stability
Substrates
Thin film transistors
Top Gate
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Zusammenfassung:The present paper reports the study of electrical characteristics and bias temperature stress (BT) stability of crystalline Indium‐Gallium oxide (IGO) dual‐gate thin film transistor (TFT) with top‐gate structure. TFT with normalized Ion over 100εA and PBTS/NBTIS of 0.35/‐2.85V was successfully fabricated. By adjusting oxygen partial pressure (O2%) and substrate temperature, we can control the wet etching rate (WER) of as‐deposited IGO film. After post annealing, crystalline IGO containing In2O3 phase with preferred orientation of (222) has been formed. The TFT characteristics uniformity and BT stability were found to depend on parameters of gate insulator (GI) deposition and pre‐treatment before GI. Based on experimental results, we propose high GI deposition temperature associated with low N2O plasma treatment power as the optimal condition for industrial production of crystalline IGO TFT.
ISSN:0097-966X
2168-0159
DOI:10.1002/sdtp.17802