Low-temperature n-type doping of insulating ultrathin amorphous indium oxide using H plasma-assisted annealing
- Authors
- Seo, Hojun; Lee, Sang Yeon; Lee, Jeongsu; Kim, Sunjin; Sul, Onejae; Seo, Hyungtak; Lee, Seung-Beck
- Issue Date
- May-2022
- Publisher
- Institute of Physics Publishing
- Keywords
- oxide semiconductors; thin-film transistor; In2O3; doping; low temperature fabrication
- Citation
- Nanotechnology, v.33, no.20, pp 1 - 10
- Pages
- 10
- Indexed
- SCIE
SCOPUS
- Journal Title
- Nanotechnology
- Volume
- 33
- Number
- 20
- Start Page
- 1
- End Page
- 10
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/170175
- DOI
- 10.1088/1361-6528/ac51ac
- ISSN
- 0957-4484
1361-6528
- Abstract
- Low-temperature process compatibility is a key factor in successfully constructing additional functional circuits on top of pre-existing circuitry without corrupting characteristics thereof, a technique that typically requires die-to-die (wafer-to-wafer) stacking and interconnecting. And against thermal annealing, which is mandatory and is possible only globally for activating amorphous oxide semiconductors, the selective control of electrical characteristics of the oxide thin-films for integrated circuit applications is challenging. Here, a low-temperature process that enables n-type doping of the designed region of insulating In2O3thin-film is demonstrated. A short hydrogen plasma treatment followed by low-temperature annealing is used to increase interstitial and substitutional hydrogen associated bond states creating shallow donor levels in the insulating In2O3surface to transform the thin-film into an n-type semiconductor. As a result, an In2O3thin-film transistor with a high on/off current ratio (>108), a field-effect mobility of 3.8 cm2V-1s-1, and a threshold voltage of ∼3.0 V has been developed. Compared to performing just thermal annealing, the H-plasma assisted annealing process resulted in an n-type In2O3thin-film transistor showing similar characteristics, while the processing time was reduced by ∼1/3 and the plasma-untreated area still remained insulating. With further development, the hydrogen plasma doping process may make possible a monolithic planar process technology for amorphous oxide semiconductors.
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