Overall reaction mechanism for a full atomic layer deposition cycle ofW films on TiN surfaces: first-principles study
- Authors
- Park, Hwanyeol; Lee, Sungwoo; Kim, Ho Jun; Woo, Daekwang; Lee, Jong Myeong; Yoon, Euijoon; Lee, Gun-Do
- Issue Date
- Nov-2018
- Publisher
- ROYAL SOC CHEMISTRY
- Citation
- RSC ADVANCES, v.8, no.68, pp.39039 - 39046
- Journal Title
- RSC ADVANCES
- Volume
- 8
- Number
- 68
- Start Page
- 39039
- End Page
- 39046
- URI
- https://scholarworks.bwise.kr/gachon/handle/2020.sw.gachon/78622
- DOI
- 10.1039/c8ra07354f
- ISSN
- 2046-2069
- Abstract
- We investigated the overall ALD reaction mechanism for W deposition on TiN surfaces based on DFT calculation as well as the detailed dissociative reactions of WF6. Our calculated results suggest that the overall reactions of the WF6 on the B-covered TiN surfaces are energetically much more favorable than the one on the TiN surfaces, which means that the high reactivity of WF6 with the B-covered TiN surface is attributed to the presence of B-covered surface made by B2H6 molecules. As a result, an effect of the B2H6 flow serves as a catalyst to decompose WF6 molecules. Two additional reaction processes right after WF6 bond dissociation, such as W substitution and BF3 desorption, were also explored to clearly understand the detailed reactions that can occur by WF6 flow. At the first additional reaction process, W atoms can be substituted into B site and covered on the TiN surfaces due to the stronger bonding nature of W with the TiN surface than B atoms. At the second additional reaction process, remaining atoms, such as B and F, can be easily desorbed as by-product, that is, BF3 because BF3 desorption is an energetically favorable reaction with a low activation energy. Furthermore, we also investigated the effect of H-2 post-treatment on W-covered TiN surface in order to remove residual F adatoms, which are known to cause severe problems that extremely degrade the characteristics of memory devices. It was found that both H-2 dissociative reaction and HF desorption can occur sufficiently well under somewhat high temperature and H-2 ambience, which is confirmed by our DFT results and previously reported experimental results. These results imply that the understanding of the role of gas molecules used for W deposition gives us insight into improving the W ALD process for future memory devices.
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Collections - 공과대학 > 기계공학과 > 1. Journal Articles
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