Direct Mapping of Crystallization-Induced Trap-State Modulation and Its Impact on Local Carrier Mobilities in Indium Oxide Thin-Film Transistors
- Authors
- Oh, Yuhyeon; Oh, Jeong Eun; Park, Seunghyo; Lee, Sang-Eun; Jeong, Jae Kyeong; Hong, Seunghun
- Issue Date
- Mar-2026
- Publisher
- AMER CHEMICAL SOC
- Keywords
- indium oxide; polycrystalline; thin-film transistor; oxygen vacancy trap; local trap-depth imaging; scanning noise microscopy
- Citation
- NANO LETTERS, v.26, no.10, pp 3434 - 3442
- Pages
- 9
- Indexed
- SCIE
SCOPUS
- Journal Title
- NANO LETTERS
- Volume
- 26
- Number
- 10
- Start Page
- 3434
- End Page
- 3442
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/214450
- DOI
- 10.1021/acs.nanolett.5c06324
- ISSN
- 1530-6984
1530-6992
- Abstract
- Crystalline oxide semiconductors are promising back-end-of-line (BEOL)-compatible channel materials for AI hardware, yet their nanoscale trap physics remains unclear. Here, we directly mapped and quantified mobility (mu), trap density (N eff), and trap depth in amorphous/nanocrystalline (a/n-) and polycrystalline (p-) In2O3 films using scanning noise microscopy with finite-element analysis. A/n-In2O3 exhibited large local variations in mu and N eff with deep trap states (similar to 0.24 eV). Upon full crystallization, p-In2O3 exhibited uniform mu and N eff with shallow trap states at grains (similar to 0.10 eV) and grain boundaries (similar to 0.12 eV). Crystallization effectively eliminated structural-disorder-induced deep states, leaving only shallow donor-like oxygen vacancy traps. This led to enhanced mu and significantly reduced N eff (and trap depth), exhibiting uniform spatial distributions with minute changes at grain boundaries. Furthermore, p-In2O3 devices achieved higher mobility, more positive threshold voltage, and improved bias stability, confirming reduced deep-trap activity and enhanced charge-transport uniformity. This work establishes a direct link between structural ordering, local trap-depth modulation, and macroscopic electrical performances of crystalline oxide channels.
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