Abstract
To improve the functionality of state-of-the-art integrated circuits, it is often necessary to create gate oxides of various thicknesses on a single chip. Currently, double oxidation is used for this purpose: a thick dielectric is created as a result of two oxidation processes, and a thin dielectric – only one. In this paper, the formation of dual gate oxide using pyrogenic oxidation and ISSG (in situ steamgeneration) is investigated. It is shown that ISSG oxidation during the creation of the 2nd oxide has a negligible effect on the thickness of the 1st thick oxide compared with pyrogenic oxidation, which is explained by the kinetics of radical oxidation of silicon.
Reference6 articles.
1. Krasnikov G.Ya. Design and technological features of submicron mosfets. 2nd edition, revised. M.: Technosphere, 2011. Р. 177 (In Russian).
2. Kar N.H., Lai L.S. Dual gate oxide formation using ISSG selective oxidation on 2nd thin oxide without influence on 1st thick oxide thickness // International Symposium on Semiconductor Manufacturing, 2005. IEEE, 2005. P. 190–192.
3. Storbeck O., Pethe W., Hayn R. A Growth Kinetics Model for the Radical Oxidation of Silicon // Materials Science Forum. Trans Tech Publications Ltd, 2008. Т. 573. P. 147–152.
4. Kee R.J. et al. The influence of pressure, fluid flow, and chemistry on the combustion-based oxidation of silicon // Proceedings of the Combustion Institute. 2000. Т. 28. № 1. P. 1381–1388.
5. Chernyaev M.V., Gorokhov S.A., Patyukov S.I., Rezvanov A.A. The Kinetics of Radical Oxidation of Silicon // Elektronnaya Tekhnika. Series 3: Microelectronics. 2022. Issue 3 (187). P. 31–44.
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