Material and Electrical Characteristics of a Thin-Film Transistor Using Cationic Composition-Controlled Atomic Layer-Deposited In–Ga–Sn–O (IGTO) Thin FilmMaterial and Electrical Characteristics of a Thin-Film Transistor Using Cationic Composition-Controlled Atomic Layer-Deposited In-Ga-Sn-O (IGTO) Thin Film
- Other Titles
- Material and Electrical Characteristics of a Thin-Film Transistor Using Cationic Composition-Controlled Atomic Layer-Deposited In-Ga-Sn-O (IGTO) Thin Film
- Authors
- Lee, Chanseul; Kim, Sunbum; Min, Kyoung Yeon; Kim, Gyulee; Kim, Minhyuk; Park, Yongjoo; Choi, Changhwan
- Issue Date
- Feb-2026
- Publisher
- American Chemical Society
- Keywords
- In−Ga−Sn−O (IGTO); atomic layer deposition (ALD); oxide semiconductor; thin film transistor (TFT); cationic composition
- Citation
- ACS Applied Electronic Materials, v.8, no.3, pp 1080 - 1087
- Pages
- 8
- Indexed
- SCIE
SCOPUS
- Journal Title
- ACS Applied Electronic Materials
- Volume
- 8
- Number
- 3
- Start Page
- 1080
- End Page
- 1087
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/211367
- DOI
- 10.1021/acsaelm.5c01836
- ISSN
- 2637-6113
2637-6113
- Abstract
- In–Ga–Sn–O (IGTO) thin-film transistors (TFTs) were fabricated, in which the metal cationic compositions of the IGTO channel were controlled by subcyclic ratio design of each precursor during atomic-layer deposition (ALD). When the number of Sn precursor subcycles increased, the cationic composition of Sn increased from 0.3 to 1.9. It was found that the field-effect mobility gradually increased, and the threshold voltage shifted negatively with higher Sn molar ratios. As a result, the devices using the IGTO channel with a cationic composition of 4.2:1.3:1.9 (In:Ga:Sn) exhibited the highest field-effect mobility of 66.9 cm2/V·s as well as the most stable behavior against external gate bias stress (ΔVth < 2 V). These characteristics are attributed to the free electrons generated by Sn4+ diffusion between In and Sn layers contributing to the conduction band during the ALD process and the effective suppression of oxygen vacancy formation with a higher Sn composition ratio.
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