Effect of polyethylene glycol on surface coating of Ta2O5 onto titanium substrate in sol-gel technique

[1] Arbuj S.S., Mulik U.P., Amalnerkar D.P., Synthesis of Ta₂O₅/TiO₂ coupled semiconductor oxide nanocomposites with high photocatalytic activity, Nanosci. Nanotechnol. Lett., 2013, 5, 968–973. Search in Google Scholar

[2] Arnould C., Volcke C., Lamarque C., Titanium modified with layer-by-layer sol–gel tantalum oxide and an organodiphosphonic acid: A coating for hydroxyapatite growth, J. Colloid Interface Sci., 2009, 336, 497–503. Search in Google Scholar

[3] Balagna C., Faga M.G., Spriano S., Tribological behavior of a Ta-based coating on a Co–Cr–Mo alloy, Surf. Coat Technol., 2014, 258, 1159–1170. Search in Google Scholar

[4] Chang Y.Y., Huang H.L., Chen H.J., Lai C.H., Wen C.Y., Antibacterial properties and cytocompatibility of tantalum oxide coatings, Surf. Coat Tech., 2014, 259, 193–198. Search in Google Scholar

[5] Fathi M., Azam F., Novel hydroxyapatite/tantalum surface coating for metallic dental implant, Mater. Lett., 2007, 61, 1238–1241. Search in Google Scholar

[6] Francisco M., Cardoso W., Gushikem Y., Surface modification with phosphoric acid of SiO₂/Nb₂O₅ prepared by the Sol-Gel method: structural−textural and acid sites studies and an ion exchange model, Langmuir, 2004, 20, 8707–8714. Search in Google Scholar

[7] Georgiev R., Georgieva B., Lazarova K., Vasileva M., Babeva T., Sol–gel tantalum pentoxide thin films with tunable refractive index for optical sensing applications, Opt. Quantum Electron., 2020, 52 (10), 1–12. Search in Google Scholar

[8] Gul C., Albayrak S., Cinici H., Characterization of Tantalum Oxide Sol–Gel-coated AZ91 Mg Alloys, Trans. Indian Inst. Met., 2020, 73 (5), 1249–1256. Search in Google Scholar

[9] Gupta S.K., Mohapatra M., Godbole S., On the unusual photoluminescence of Eu³⁺ in α-Zn₂P₂O₇: a time resolved emission spectrometric and Judd–O felt study, RSC Adv., 2013, 3, 20046–20053. Search in Google Scholar

[10] Hee A.C., Jamali S.S., Bendavid A., Martin P.J., Kong C., Zhao Y., Corrosion behaviour and adhesion properties of sputtered tantalum coating on Ti₆Al₄V substrate, Surf. Coat Tech., 2016, 307, 666–675. Search in Google Scholar

[11] Innocentini M., Faleiros R., Pisani R., Permeability of porous gelcast scaffolds for bone tissue engineering, J. Porous Mater., 2010, 17, 615–627. Search in Google Scholar

[12] Kim H.-W., Kim H.-E., Knowles J.C., Fluor-hydroxyapatite sol–gel coating on titanium substrate for hard tissue implants, Biomaterials, 2004, 25, 3351–3358. Search in Google Scholar

[13] Kłonica M., Kuczmaszewski J., Modification of Ti₆Al₄V Titanium Alloy Surface Layer in the Ozone Atmosphere, Mater. Des., 2019, 12, 2113. Search in Google Scholar

[14] Kokubo T., Design of bioactive bone substitutes based on biomineralization process, Mater. Sci. Eng., 2005, 25, 97–104. Search in Google Scholar

[15] Kulisch W., Gilliland D., Ceccone G., Tantalum pentoxide as a material for biosensors: deposition, properties and applications, [in:] Nanostructured Materials for Advanced Technological Applications, J. Reithmaier, P. Petkov, W. Kulisch, C. Popov (Eds.), Springer, 2009, 509–524. Search in Google Scholar

[16] Li X., Wang, L., Yu X., Feng Y., Wang C., Yang K., Su D., Tantalum coating on porous Ti₆Al₄V scaffold using chemical vapor deposition and preliminary biological evaluation, Mater. Sci. Eng. C, 2013, 33 (5), 2987–2994. Search in Google Scholar

[17] Maho A., Linden S., Arnould C., Detriche S., Delhalle J., Mekhalif Z., Tantalum oxide/carbon nanotubes composite coatings on titanium, and their functionalization with organophosphonic molecular films: A high quality scaffold for hydroxyapatite growth, J. Colloid Interface Sci., 2012, 371 (1), 150–158. Search in Google Scholar

[18] Miyazaki T., Kim H.-M., Kokubo T., Induction and acceleration of bonelike apatite formation on tantalum oxide gel in simulated body fluid, J. Solgel Sci. Technol., 2001, 21, 83–88. Search in Google Scholar

[19] Ndiege N., Wilhoite T., Subramanian V., Sol−Gel Synthesis of Thick Ta₂O₅ Films, Chem. Mater., 2007, 19, 3155–3161. Search in Google Scholar

[20] Pramanik S., Ataollahi F., Pingguan-Murphy B., Oshkour A.A., Abu Osman N.A., In vitro study of surface modified poly (ethylene glycol)-impregnated sintered bovine bone scaffolds on human fibroblast cells, Sci. Rep., 2015, 5, 9806. Search in Google Scholar

[21] Rao K.T.V., Souzanchi S., Yuan Z., One-pot sol–gel synthesis of a phosphated TiO₂ catalyst for conversion of monosaccharide, disaccharides, and polysaccharides to 5-hydroxymethylfurfural, New J. Chem., 2019, 43, 12483–12493. Search in Google Scholar

[22] Sathasivam S., Williamson B.A., Kafizas A., Althabaiti S.A., Obaid A.Y., Basahel S.N., Scanlon D.O., Carmalt C.J., Parkin I.P., Computational and experimental study of Ta₂O₅ thin films, J. Phys. Chem. C, 2017, 121 (1), 202–210. Search in Google Scholar

[23] Sato M., Slamovich E.B., Webster T.J., Enhanced osteoblast adhesion on hydrothermally treated hydroxyapatite/titania /poly (lactide-co-glycolide) sol–gel titanium coatings, Biomaterials, 2005, 26, 1349–1357. Search in Google Scholar

[24] Shorvazi S., Kermani F., Mollazadeh S., Coating Ti₆Al₄V substrate with the triple-layer glass-ceramic compositions using sol–gel method; the critical effect of the composition of the layers on the mechanical and in vitro biological performance, J. Solgel Sci. Technol., 2020, 94, 743–753. Search in Google Scholar

[25] Siu J.H., Li L.K., An investigation of the effect of surface roughness and coating thickness on the friction and wear behaviour of a commercial MoS₂–metal coating on AISI 400C steel, Wear, 2000, 237, 283–287. Search in Google Scholar

[26] Stoch A., Jastrzębski W., Długoń E., Sol–gel derived hydroxyapatite coatings on titanium and its alloy Ti₆Al₄V, J. Mol. Struct., 2005, 744, 633–640. Search in Google Scholar

[27] Sun Y.S., Chang J.H., Huang H.H., Corrosion resistance and biocompatibility of titanium surface coated with amorphous tantalum pentoxide, Thin. Solid. Films, 2013, 528, 130–135. Search in Google Scholar

[28] Sun Y.S., Chang J.H., Huang H.H., Using submicroporous Ta oxide coatings deposited by a simple hydrolysis–condensation process to increase the biological responses to Ti surface, Surf. Coat Tech., 2014, 259, 199–205. Search in Google Scholar

[29] Taddei P., Tinti A., Reggiani M., In vivo bioactivity of titanium and fluorinated apatite coatings for orthopaedic implants: a vibrational study, J. Mol. Struct., 2003, 651, 427–431. Search in Google Scholar

[30] Tepehan F.Z., Ghodsi F.E., Ozer N., Optical properties of sol–gel dip-coated Ta₂O₅ films for electrochromic applications, Sol Energy Mater. Sol Cells, 1999, 59, 265–275. Search in Google Scholar

[31] Tripathy A., Pramanik S., Manna A., Azrin Shah N.F., Shasmin H.N., Radzi Z., Abu Osman N.A., Synthesis and characterizations of novel Ca-Mg-Ti-Fe-oxides-based ceramic nanocrystals and flexible film of polydimethylsiloxane composite with improved mechanical and dielectric properties for sensors, Sensors, 2016, 16, 292. Search in Google Scholar

[32] Wan T., Stylios G.K., Effects of coating process on the surface roughness of coated fabrics, J. Text Inst., 2017, 108, 712–719. Search in Google Scholar

[33] Wolf M.J., Roitsch S., Mayer J., Nijmeijer A., Bouwmeester H.J., Fabrication of ultrathin films of Ta₂O₅ by a sol–gel method, Thin Solid Films, 2013, 527, 354–357. Search in Google Scholar

[34] Xu J., Ke Bao X., Fu T., Lyu Y., Munroe P., Xie Z.H., In vitro biocompatibility of a nanocrystalline β-Ta₂O₅ coating for orthopaedic implants, Ceram. Int., 2018, 44 (5), 4660–4675. Search in Google Scholar

[35] Yu J., Zhao X., Zhao Q., Effect of surface structure on photocatalytic activity of TiO₂ thin films prepared by sol-gel method, Thin Solid Films, 2000, 379, 7–14. Search in Google Scholar

[36] Zhang P., Lin D., Zhu Y., In-situ high temperature laserinduced damage of sol-gel Ta₂O₅ films with different dual additives, Thin Solid Films, 2020, 693, 137723. Search in Google Scholar