https://oldena.lpnu.ua/handle/ntb/51784| Title: | Modification of the Silicon Surface by the Gold Nanoparticle by Galvanic Replacement |
| Authors: | Shepida, Mariana Zozylya, Galyna Dobrovetska, Oksana |
| Affiliation: | Lviv Polytechnic National University |
| Bibliographic description (Ukraine): | Shepida M. Modification of the Silicon Surface by the Gold Nanoparticle by Galvanic Replacement / Mariana Shepida, Galyna Zozylya, Oksana Dobrovetska // Litteris et Artibus : proceedings, 23–25 November 2018, Lviv. — Lviv : Lviv Politechnic Publishing House, 2018. — P. 250–253. — (7th International academic conference “Chemistry & chemical technology 2018” (CCT-2018)). |
| Bibliographic description (International): | Shepida M. Modification of the Silicon Surface by the Gold Nanoparticle by Galvanic Replacement / Mariana Shepida, Galyna Zozylya, Oksana Dobrovetska // Litteris et Artibus : proceedings, 23–25 November 2018, Lviv. — Lviv : Lviv Politechnic Publishing House, 2018. — P. 250–253. — (7th International academic conference “Chemistry & chemical technology 2018” (CCT-2018)). |
| Is part of: | Litteris et Artibus : proceedings, 2018 |
| Conference/Event: | 8th International youth science forum «Litteris et Artibus» |
| Journal/Collection: | Litteris et Artibus : proceedings |
| Issue Date: | 22-Nov-2018 |
| Publisher: | Видавництво Львівської політехніки Lviv Politechnic Publishing House |
| Place of the edition/event: | Львів Lviv |
| Temporal Coverage: | 23–25 November 2018, Lviv |
| Keywords: | galvanic replacement nanoparticles gold nanofilm silicon surface aprotic solvents |
| Number of pages: | 4 |
| Page range: | 250-253 |
| Start page: | 250 |
| End page: | 253 |
| Abstract: | The results of studies of the deposition of gold nanoparticles on the surface of silicon by galvanic substitution are presented. The process conditions under which a nano-sized precipitate is formed in the organic aprotic solvents are investigated. The effect of temperature and duration of galvanic substitution on the morphology of the modified surface, the geometry of the sediment particles and their size distribution is studied. |
| URI: | https://ena.lpnu.ua/handle/ntb/51784 |
| ISBN: | 978-966-941-294-2 |
| Copyright owner: | © Національний університет “Львівська політехніка”, 2018 |
| References (Ukraine): | [1] A. Raygani, L. Magagnin. “Gold metallization of silicon by galvanic displacement”. Electrochemical Society Transactions, vol. 41, pp. 3-8, 2012. [2] H. Itasaka, M. Nishi, M. Shimizu, and K. Hirao. “Growth of nanogold at interfaces between locally induced naked silicon surfaces and pure HAuCl4 solutions”. Journal of The Electrochemical Society, vol. 163, pp. D743–D746, 2016. [3] A. Lahiri and S.-I. Kobayashi. “Electroless deposition of gold on silicon and its potential applications: review”. Surface Engineering, vol. 32, pp. 321-337, 2016, [4] S.S. Djokic. “Galvanic Deposition of Copper, Silver and Gold on Silicon Surfaces from Fluoride Free Aqueous Solutions”. Electrochemical Society Transactions, vol. 75, pp. 15–25, 2017. [5] J. Kye, M. Shin, B. Lim, J.-W. Jang. “Platinum monolayer electrocatalyst on gold nanostructures on siliconfor photoelectrochemical hydrogen evolution”. American Chemical Society, vol. 7, pp. 6017–6023, 2013. [6] A. Gutes, C. Carraro and R. Maboudian. “Ultrasmooth gold thin films by self-limiting galvanic displacement on silicon”. American Chemical Society Applide Material Interfaces, vol.3, pp. 1581–1584, 2011. [7] N. Yamada, H. Atsushiba, S. Sakamoto, N. Fukumuro, et al. “Effect of epitaxial growth of gold nanoparticles on Si substrates on adhesion of electrolessly deposited metal films”. Electrochemical Society Transactions, vol. 69, pp. 59-63, 2015. [8] S.Y. Sayed, F. Wang, M. Malac, A. Meldrum, et al. “Heteroepitaxial growth of gold nanostructures on silicon by galvanic displacement”. American Chemical Society NANO, vol. 3, pp. 2809–2817, 2009. [9] L. Magagnin, R. Maboudian and C. Carraro. “Gold deposition by galvanic displacement on semiconductor surfaces: effect of substrate on adhesion”. Journal of the Physical Chemistry, vol.106, pp. 401-407, 2002. [10] O. Kuntyi, M. Shepida, L. Sus, G. Zozulya, S. Korniy. “Modification of Silicon Surface with Silver, Gold and Palladium Nanostructures via Galvanic Substitution in DMSO and DMF Solutions”. Chemistry & Chemical Technology, vol. 12, pp. 305-309, 2018. [11] O.Ya. Dobrovets’ka, O.I. Kuntyi, G.I. Zozulya, I.V. Saldan, O.V. Reshetnyak. “Galvanic Deposition of Gold and Palladium on Magnesium by the method of Substitution”. Materials Science, vol. 51, pp. 418– 423, 2015. |
| References (International): | [1] A. Raygani, L. Magagnin. "Gold metallization of silicon by galvanic displacement". Electrochemical Society Transactions, vol. 41, pp. 3-8, 2012. [2] H. Itasaka, M. Nishi, M. Shimizu, and K. Hirao. "Growth of nanogold at interfaces between locally induced naked silicon surfaces and pure HAuCl4 solutions". Journal of The Electrochemical Society, vol. 163, pp. D743–D746, 2016. [3] A. Lahiri and S.-I. Kobayashi. "Electroless deposition of gold on silicon and its potential applications: review". Surface Engineering, vol. 32, pp. 321-337, 2016, [4] S.S. Djokic. "Galvanic Deposition of Copper, Silver and Gold on Silicon Surfaces from Fluoride Free Aqueous Solutions". Electrochemical Society Transactions, vol. 75, pp. 15–25, 2017. [5] J. Kye, M. Shin, B. Lim, J.-W. Jang. "Platinum monolayer electrocatalyst on gold nanostructures on siliconfor photoelectrochemical hydrogen evolution". American Chemical Society, vol. 7, pp. 6017–6023, 2013. [6] A. Gutes, C. Carraro and R. Maboudian. "Ultrasmooth gold thin films by self-limiting galvanic displacement on silicon". American Chemical Society Applide Material Interfaces, vol.3, pp. 1581–1584, 2011. [7] N. Yamada, H. Atsushiba, S. Sakamoto, N. Fukumuro, et al. "Effect of epitaxial growth of gold nanoparticles on Si substrates on adhesion of electrolessly deposited metal films". Electrochemical Society Transactions, vol. 69, pp. 59-63, 2015. [8] S.Y. Sayed, F. Wang, M. Malac, A. Meldrum, et al. "Heteroepitaxial growth of gold nanostructures on silicon by galvanic displacement". American Chemical Society NANO, vol. 3, pp. 2809–2817, 2009. [9] L. Magagnin, R. Maboudian and C. Carraro. "Gold deposition by galvanic displacement on semiconductor surfaces: effect of substrate on adhesion". Journal of the Physical Chemistry, vol.106, pp. 401-407, 2002. [10] O. Kuntyi, M. Shepida, L. Sus, G. Zozulya, S. Korniy. "Modification of Silicon Surface with Silver, Gold and Palladium Nanostructures via Galvanic Substitution in DMSO and DMF Solutions". Chemistry & Chemical Technology, vol. 12, pp. 305-309, 2018. [11] O.Ya. Dobrovets’ka, O.I. Kuntyi, G.I. Zozulya, I.V. Saldan, O.V. Reshetnyak. "Galvanic Deposition of Gold and Palladium on Magnesium by the method of Substitution". Materials Science, vol. 51, pp. 418– 423, 2015. |
| Content type: | Conference Abstract |
| Appears in Collections: | Litteris et Artibus. – 2018 р. |
| File | Description | Size | Format | |
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| 2018_Shepida_M-Modification_of_the_Silicon_250-253.pdf | 839.35 kB | Adobe PDF | View/Open | |
| 2018_Shepida_M-Modification_of_the_Silicon_250-253__COVER.png | 466.54 kB | image/png | View/Open |
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