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27-07-2023

Features of Plasma Coating Formation from Silicon Carbide on Titanium Alloy VT6

Authors: O. A. Markelova, V. A. Koshuro, E. O. Osipova, A. A. Fomin

Published in: Metallurgist | Issue 3-4/2023

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Abstract

Plasma spraying is used to prepare a silicon carbide (SiC) coating on a titanium alloy VT6 base. A coating is formed by superposition of molten particles up to 90 μm in size with rounded microparticles up to 10 μm in size secured on their surface. Coating microhardness is not uniform, there are areas with 1200–1500 HV and 450–700 HV, and wear resistance corresponds to the class KI7/1. Coatings exhibit hydrophilic properties. Surface roughness is Ra 2.68 μm.

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Literature
1.
go back to reference L. Fiorillo, M. Cicciu, T. F. Tozum, et al., “Endosseous dental implant materials and clinical outcomes of different alloys: A systematic review,” Materials, 15, No. 5, 1979 (2022). L. Fiorillo, M. Cicciu, T. F. Tozum, et al., “Endosseous dental implant materials and clinical outcomes of different alloys: A systematic review,” Materials, 15, No. 5, 1979 (2022).
2.
go back to reference M. M. Mutter, R. H. Jabbar, and A. I. Khudiar, “Synthesis and characterization of TiO2: Al thin films for bacteria resistance in the implanted dental,” J. Australian Ceramic Society, 58, No. 1, 145–149 (2022).CrossRef M. M. Mutter, R. H. Jabbar, and A. I. Khudiar, “Synthesis and characterization of TiO2: Al thin films for bacteria resistance in the implanted dental,” J. Australian Ceramic Society, 58, No. 1, 145–149 (2022).CrossRef
3.
go back to reference D. Xi and I. Wong, “ Titanium and implantology: A review in dentistry,” J. Biological Regulators and Homeostatic Agents, 35, No. 1, 63–72 (2021). D. Xi and I. Wong, “ Titanium and implantology: A review in dentistry,” J. Biological Regulators and Homeostatic Agents, 35, No. 1, 63–72 (2021).
4.
go back to reference H. Vaghela and K. Eaton, “Is zirconia a viable alternative to titanium for dental implantology?” The European J. Prosthodontics and Restorative Dentistry, 30, No. 1, 1–13 (2022). H. Vaghela and K. Eaton, “Is zirconia a viable alternative to titanium for dental implantology?” The European J. Prosthodontics and Restorative Dentistry, 30, No. 1, 1–13 (2022).
5.
go back to reference V. V. Luk’yachenko and M. G. Maslyasova, “ Metals in implantation,” Ortopedia, Travmatologiya i Protezirovaniya, No. 3 (580), 130–132 (2010). V. V. Luk’yachenko and M. G. Maslyasova, “ Metals in implantation,” Ortopedia, Travmatologiya i Protezirovaniya, No. 3 (580), 130–132 (2010).
6.
go back to reference A. A. Fomin, “ Plasma-induced preparation of titanium-hydroxyapatite coatings upon dental implants,” Vestn. Saratov Gos. Tekhn. Univ., 2, No. 1(32), 49–58 (2008). A. A. Fomin, “ Plasma-induced preparation of titanium-hydroxyapatite coatings upon dental implants,” Vestn. Saratov Gos. Tekhn. Univ., 2, No. 1(32), 49–58 (2008).
7.
go back to reference G. A. Volozhin, A. P. Alekhin, A. M. Markeev, D. V. Tetyukhin, E. N. Kozlov, and M. A. Stepanova, “ Effect of physicochemical properties of titanium implants and modification methods on osteo-integration indices. Part 1. Main ortho-integration indices in relation to implant surface properties,” Inst. Stomatologiya, No. 3 (44), 81–83 (2009). G. A. Volozhin, A. P. Alekhin, A. M. Markeev, D. V. Tetyukhin, E. N. Kozlov, and M. A. Stepanova, “ Effect of physicochemical properties of titanium implants and modification methods on osteo-integration indices. Part 1. Main ortho-integration indices in relation to implant surface properties,” Inst. Stomatologiya, No. 3 (44), 81–83 (2009).
8.
go back to reference E. Nikoomanzari, M. Karbasi, W. C. M. A. Melo, et al, “ Impressive strides in antibacterial performance amelioration of Ti-based implants via plasma electrolytic oxidation (PEO): A review of the recent advancements,” Chemical Engineering J., 441, 136003 (2022).CrossRef E. Nikoomanzari, M. Karbasi, W. C. M. A. Melo, et al, “ Impressive strides in antibacterial performance amelioration of Ti-based implants via plasma electrolytic oxidation (PEO): A review of the recent advancements,” Chemical Engineering J., 441, 136003 (2022).CrossRef
9.
go back to reference A. Khaskhoussi, L. Calabrese, M. Curro, et al., “Effect of the compositions on the biocompatibility of new alumina-zirconia-titania dental ceramic composites,” Materials, 13, No. 6, 1374 (2020). A. Khaskhoussi, L. Calabrese, M. Curro, et al., “Effect of the compositions on the biocompatibility of new alumina-zirconia-titania dental ceramic composites,” Materials, 13, No. 6, 1374 (2020).
10.
go back to reference C. Piconi and M. Sandri, “New materials for dental implantology,” Key Engineering Materials, 750, 189–194 (2017).CrossRef C. Piconi and M. Sandri, “New materials for dental implantology,” Key Engineering Materials, 750, 189–194 (2017).CrossRef
11.
go back to reference M. Yu. Kollerov, V. S. Spektor, A. M. Mamomnov, S. V. Skvortsova, D. E. Gusev, and G. V. Gurtovaya, “Problems and prospects of using titanium alloys in medicine,” Titan, No. 2, 42–53 (2015). M. Yu. Kollerov, V. S. Spektor, A. M. Mamomnov, S. V. Skvortsova, D. E. Gusev, and G. V. Gurtovaya, “Problems and prospects of using titanium alloys in medicine,” Titan, No. 2, 42–53 (2015).
12.
go back to reference M. B. Ivanov, Yu. R. Kolobov, E. V. Golosov, I. N. Kuz’menko, V. P. Veinov, D. A. Nechaenko, and E. S. Kungurtsev, “Mechanical properties of mass produced nanostructured titanium,” Ross. Nanotech., 6, No. 5-6, 108–114 (2011). M. B. Ivanov, Yu. R. Kolobov, E. V. Golosov, I. N. Kuz’menko, V. P. Veinov, D. A. Nechaenko, and E. S. Kungurtsev, “Mechanical properties of mass produced nanostructured titanium,” Ross. Nanotech., 6, No. 5-6, 108–114 (2011).
13.
go back to reference I. A. Voronov, “Nanohardness of basic material “ftoraks” of a silicon carbide coating,” Ross. Stomatol., 20, No. 1, 4–6 (2016). I. A. Voronov, “Nanohardness of basic material “ftoraks” of a silicon carbide coating,” Ross. Stomatol., 20, No. 1, 4–6 (2016).
14.
go back to reference C. Fares, S. M. Hsu, M. Xian, X. Xia, F. Ren, J. J. Mecholsky, L. Gonzaga, and J. Esquivel-Upshaw, “Demonstration of a SiC protective coating for titanium implants,” Materials, 13, No. 15, 3321 (2020). C. Fares, S. M. Hsu, M. Xian, X. Xia, F. Ren, J. J. Mecholsky, L. Gonzaga, and J. Esquivel-Upshaw, “Demonstration of a SiC protective coating for titanium implants,” Materials, 13, No. 15, 3321 (2020).
15.
go back to reference S. Santavirta, M. Takagi, L. Nordsletten, et al., “ Biocompatibility of silicon carbide in colony formation test in vitro,” Arch. Orth. Traum. Surg., 118, 89–91 (1988).CrossRef S. Santavirta, M. Takagi, L. Nordsletten, et al., “ Biocompatibility of silicon carbide in colony formation test in vitro,” Arch. Orth. Traum. Surg., 118, 89–91 (1988).CrossRef
16.
go back to reference S. Saddow, C. Coletti, C. Frewin, N. Schettini, A. Oliveros, and M. Jaroszeski, “Single-crystal silicon carbide: A biocompatible and hemocompatible semiconductor for advanced biomedical applications,” MRS Proceedings, 1246, 1246–B08–08 (2010). S. Saddow, C. Coletti, C. Frewin, N. Schettini, A. Oliveros, and M. Jaroszeski, “Single-crystal silicon carbide: A biocompatible and hemocompatible semiconductor for advanced biomedical applications,” MRS Proceedings, 1246, 1246–B08–08 (2010).
17.
go back to reference D. K. Owens and R. C. Wendt, “ Estimation of the surface free energy of polymers,” J. Apply. Polym. Sci., 13, No. 8, 1741–1747 (1969).CrossRef D. K. Owens and R. C. Wendt, “ Estimation of the surface free energy of polymers,” J. Apply. Polym. Sci., 13, No. 8, 1741–1747 (1969).CrossRef
18.
go back to reference G. D. Krotova, V. Yu. Dubrovin, V. A. Titov, and T. G. Shikova, Technology of Electronic Engineering Materials and Objects: Laboratory Course [in Russian], GOU VPO Ivan. Gos. Khim. Tekhnol Univ., Ivanovo (2007). G. D. Krotova, V. Yu. Dubrovin, V. A. Titov, and T. G. Shikova, Technology of Electronic Engineering Materials and Objects: Laboratory Course [in Russian], GOU VPO Ivan. Gos. Khim. Tekhnol Univ., Ivanovo (2007).
19.
go back to reference A. A. Fomin, Scientific Basis of Thermal Processes for Preparing Oxide Coatings upon Titanium Medicinal Objects Using a High-Frequency Current, Diss. Doct. Techn. Sci., 05.09.10; 05.16.01. Saratov (2017). A. A. Fomin, Scientific Basis of Thermal Processes for Preparing Oxide Coatings upon Titanium Medicinal Objects Using a High-Frequency Current, Diss. Doct. Techn. Sci., 05.09.10; 05.16.01. Saratov (2017).
20.
go back to reference M. Tului, B. Giambi, S. Lionetti, G. Pulci, F. Sarasini, and T. Valente, “Silicon carbide based plasma sprayed coatings,” Surface and Coatings Technology, 207, 182–189 (2012).CrossRef M. Tului, B. Giambi, S. Lionetti, G. Pulci, F. Sarasini, and T. Valente, “Silicon carbide based plasma sprayed coatings,” Surface and Coatings Technology, 207, 182–189 (2012).CrossRef
21.
go back to reference F. Mubarok and N. Espallargas, “ Suspension plasma spraying of sub-micron silicon carbide composite coatings,” J. Therm. Spray Tech., 24, 817–825 (2015).CrossRef F. Mubarok and N. Espallargas, “ Suspension plasma spraying of sub-micron silicon carbide composite coatings,” J. Therm. Spray Tech., 24, 817–825 (2015).CrossRef
22.
go back to reference A. S. Rudenkov, A. V. Rogachev, D. G. Piliptsov, A. N. Kupo, A. S. Dobiyakha, P. A. Puchnikov, and A. A. Dal’skii, “ Structural properties of carbon coatings alloyed with silicon,” Fund. Probl. Radio. Pribor., 18, No. 2, 322–325 (2018). A. S. Rudenkov, A. V. Rogachev, D. G. Piliptsov, A. N. Kupo, A. S. Dobiyakha, P. A. Puchnikov, and A. A. Dal’skii, “ Structural properties of carbon coatings alloyed with silicon,” Fund. Probl. Radio. Pribor., 18, No. 2, 322–325 (2018).
23.
go back to reference I. A. Ivanov, “ Provision of component surface quality with vacuum-plasma coatings,” Probl. Inzh.-Ped Obraz, Respub. Belarus’, 317–319 (2009). I. A. Ivanov, “ Provision of component surface quality with vacuum-plasma coatings,” Probl. Inzh.-Ped Obraz, Respub. Belarus’, 317–319 (2009).
24.
go back to reference Yu. S, Chyesov and E. A. Zverev, “ Procedure for applying plasma wear-resistant coatings,” Nauch. Vestn. NGTU, 55, No. 2, 156–165 (2014). Yu. S, Chyesov and E. A. Zverev, “ Procedure for applying plasma wear-resistant coatings,” Nauch. Vestn. NGTU, 55, No. 2, 156–165 (2014).
25.
go back to reference S. V. Novikov, A. P. Topolyanskii, and P. A. Toployanskii, “Thin-film coatings for dental implants with minimum roughness,” Coll. 18th Internat. Sci.-Pract. Conf. “Strengthening technology, coating application and repair: theory and practice,” Izd. Politekhn, S. V. Novikov, A. P. Topolyanskii, and P. A. Toployanskii, “Thin-film coatings for dental implants with minimum roughness,” Coll. 18th Internat. Sci.-Pract. Conf. “Strengthening technology, coating application and repair: theory and practice,” Izd. Politekhn,
Metadata
Title
Features of Plasma Coating Formation from Silicon Carbide on Titanium Alloy VT6
Authors
O. A. Markelova
V. A. Koshuro
E. O. Osipova
A. A. Fomin
Publication date
27-07-2023
Publisher
Springer US
Published in
Metallurgist / Issue 3-4/2023
Print ISSN: 0026-0894
Electronic ISSN: 1573-8892
DOI
https://doi.org/10.1007/s11015-023-01520-5

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