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Dissociation Kinetics of Trapped Hydrogen in High-dose Hydrocarbon-Molecular-Ion-Implanted Silicon during Rapid Thermal Annealing
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- Kadono Takeshi
- SUMCO Corporation Faculity of Engineering, University of Miyazaki
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- Okuyama Ryosuke
- SUMCO Corporation
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- Hirose Ryo
- SUMCO Corporation
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- Kobayashi Koji
- SUMCO Corporation
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- Onaka-Masada Ayumi
- SUMCO Corporation
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- Shigematsu Satoshi
- SUMCO Corporation
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- Koga Yoshihiro
- SUMCO Corporation
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- Okuda Hidehiko
- SUMCO Corporation
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- Fukuyama Atsuhiko
- Faculity of Engineering, University of Miyazaki
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- Kurita Kazunari
- SUMCO Corporation
Description
<p>We investigated the annealing behavior of hydrogen in a high-dose hydrocarbon-molecular-ion-implanted silicon during rapid thermal annealing (RTA). Gettering sinks in the high-dose hydrocarbon-molecular-ion-implanted region are formed not only at carbon-related defects but also at defects related to the amorphous layer after RTA. The concentration of hydrogen trapped by the defects was analyzed by secondary ion mass spectrometry (SIMS). As a result, the concentration of hydrogen trapped by the amorphous-related defects was found to be higher than that of hydrogen trapped by carbon-related defects with increasing temperature. The dissociation activation energy of trapped hydrogen at each type of defect was estimated using the consecutive reaction model. The dissociation energies at amorphous-related and carbon-related defects are 0.94 ± 0.22 and 0.67 ± 0.12 eV, respectively. The hydrogen trapped in the amorphous-related defects is considered to be in a bonding state with multivacancies, such as H2–V6. On the other hand, its bonding state in the carbon-related defects is assumed to be C–H2 in carbon and self-interstitial silicon (Cs–I) clusters and H2–V in tetrahedral (Td) sites. Therefore, a high gettering capability of hydrogen can be expected by forming the amorphous-related defects peculiar to the high-dose implantation conditions.</p>
Journal
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- e-Journal of Surface Science and Nanotechnology
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e-Journal of Surface Science and Nanotechnology 20 (3), 167-173, 2022-06-30
The Japan Society of Vacuum and Surface Science
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Details 詳細情報について
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- CRID
- 1390574655178725760
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- ISSN
- 13480391
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- Text Lang
- en
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- Data Source
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- JaLC
- Crossref
- OpenAIRE
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- Abstract License Flag
- Allowed