Cerium Oxide Nanoparticles as an Accelerating Agent for Zinc Phosphate Coatings with Enhanced Corrosion Resistance
Subject Areas : Corrosion and protection of materialsMohammad-mehdi Akbari 1 , Behrooz Shayegh Boroujeny 2 , Mehdi Raeissi 3
1 - Department of Engineering, Shahrekord University, Shahrekord, Iran
2 - Department of Engineering, Shahrekord University, Shahrekord, Iran
3 - Department of Engineering, Shahrekord University, Shahrekord, Iran
Keywords:
Abstract :
[1] L. Niu, R. Guo, C. Tang, H. Guo, J. Chen, "Surface characterization and corrosion resistance of fluoferrite conversion coating on carbon steel" Surface and Coatings Technology, Vol. 300, 2016, pp. 110.
[2] C.-c. Jiang, Y.-k. Cao, G.-y. Xiao, R.-f. Zhu, Y.-p. Lu, "A review on the application of inorganic nanoparticles in chemical surface coatings on metallic substrates" RSC advances, Vol. 7, 2017, pp. 7531.
[3] O. Girčienė, R. Ramanauskas, L. Gudavičiūtė, A. Martušienė, "The effect of phosphate coatings on carbon steel protection from corrosion in a chloride-contaminated alkaline solution" J. of CHEMIJA, Vol. 24, 2013, pp. 251.
[4] B. Ramezanzadeh, M. Akbarian, M. Ramezanzadeh, M. Mahdavian, E. Alibakhshi, P. Kardar, "Corrosion protection of steel with zinc phosphate conversion coating and post-treatment by hybrid organic-inorganic sol-gel based silane film" Journal of The Electrochemical Society, Vol. 164, 2017, pp. C224.
[5] S. Eidivandi, B.S. Boroujeny, A. Dustmohammadi, E. Akbari, "The effect of surface mechanical attrition treatment (SMAT) time on the crystal structure and electrochemical behavior of phosphate coatings" Journal of Alloys and Compounds, Vol. 821, 2020, pp. 153252.
[6] C. Galvan-Reyes, J. Fuentes-Aceituno, A. Salinas-Rodríguez, "The role of alkalizing agent on the manganese phosphating of a high strength steel part 1: The individual effect of NaOH and NH4OH" Surface and Coatings Technology, Vol. 291, 2016, pp. 179.
[7] B. Ramezanzadeh, H. Vakili, R. Amini, "The effects of addition of poly (vinyl) alcohol (PVA) as a green corrosion inhibitor to the phosphate conversion coating on the anticorrosion and adhesion properties of the epoxy coating on the steel substrate" Applied Surface Science, Vol. 327, 2015, pp. 174.
[8] M. Morks, P. Corrigan, N. Birbilis, I. Cole, "A green MnMgZn phosphate coating for steel pipelines transporting CO2 rich fluids" Surface and Coatings Technology, Vol. 210, 2012, pp. 183.
[9] M. Farias, C. Santos, Z. Panossian, A. Sinatora, "Friction behavior of lubricated zinc phosphate coatings" Wear, Vol. 266, 2009, pp. 873.
[10] G. Parker, Encyclopedia of materials: science and technology, 2001.
[11] N. Bay, Metal forming and lubrication, Encyclopedia of Materials: Science and Technology, Elsevier2000, pp. 5377-5380.
[12] M. Fouladi, A. Amadeh, "Effect of phosphating time and temperature on microstructure and corrosion behavior of magnesium phosphate coating" Electrochimica Acta, Vol. 106, 2013, pp. 1.
[13] J. Popić, B. Jegdić, J. Bajat, Đ. Veljović, S. Stevanović, V. Mišković-Stanković, "The effect of deposition temperature on the surface coverage and morphology of iron-phosphate coatings on low carbon steel" Applied Surface Science, Vol. 257, 2011, pp. 10855.
[14] A. Valanezhad, K. Tsuru, M. Maruta, G. Kawachi, S. Matsuya, K. Ishikawa, "Zinc phosphate coating on 316L-type stainless steel using hydrothermal treatment" Surface and Coatings Technology, Vol. 205, 2010, pp. 2538.
[15] S. Jegannathan, T.S. Narayanan, K. Ravichandran, S. Rajeswari, "Formation of zinc phosphate coating by anodic electrochemical treatment" Surface and Coatings Technology, Vol. 200, 2006, pp. 6014.
[16] B.-i. LIN, J.-T. Lu, K. Gang, L. Jun, "Growth and corrosion resistance of molybdate modified zinc phosphate conversion coatings on hot-dip galvanized steel" Transactions of Nonferrous Metals Society of China, Vol. 17, 2007, pp. 755.
[17] T.S. Narayanan, S. Jegannathan, K. Ravichandran, "Corrosion resistance of phosphate coatings obtained by cathodic electrochemical treatment: Role of anode–graphite versus steel" Progress in organic coatings, Vol. 55, 2006, pp. 355.
[18] G. Li, L. Niu, J. Lian, Z. Jiang, "A black phosphate coating for C1008 steel" Surface and Coatings Technology, Vol. 176, 2004, pp. 215.
[19] M. Sheng, Y. Wang, Q. Zhong, H. Wu, Q. Zhou, H. Lin, "The effects of nano-SiO2 additive on the zinc phosphating of carbon steel" Surface and Coatings Technology, Vol. 205, 2011, pp. 3455.
[20] F. Fang, J.-h. Jiang, S.-Y. Tan, A.-b. Ma, J.-q. Jiang, "Characteristics of a fast low-temperature zinc phosphating coating accelerated by an ECO-friendly hydroxylamine sulfate" Surface and Coatings Technology, Vol. 204, 2010, pp. 2381.
[21] Y. Tian, W. Qiu, Y. Xie, H. Huang, J. Hu, L. Zhong, X. Jiang, X. Zhang, "Melatonin as an accelerating agent for phosphate chemical conversion coatings on mild steel with enhanced corrosion resistance" Journal of the Electrochemical Society, Vol., 2020, pp.
[22] C.-c. Jiang, R.-f. Zhu, G.-y. Xiao, Y.-z. Zheng, L.-l. Wang, Y.-p. Lu, "Effect of nano-SiO2 particles and sol on phosphate conversion coatings on 35CrMnSi steel" Journal of The Electrochemical Society, Vol. 163, 2016, pp. C571.
[23] X. Tan, F. Nan, Performance of Modified Nano-SiO2 Composite Phosphating Coating on the Surface of Steel, IOP Conference Series: Materials Science and Engineering, IOP Publishing, 2020, p. 012002.
[24] M. Tamilselvi, P. Kamaraj, M. Arthanareeswari, S. Devikala, J.A. Selvi, "Development of nano SiO2 incorporated nano zinc phosphate coatings on mild steel" Applied Surface Science, Vol. 332, 2015, pp. 12.
[25] S. Shibli, F. Chacko, "Development of nano TiO2-incorporated phosphate coatings on hot dip zinc surface for good paintability and corrosion resistance" Applied Surface Science, Vol. 257, 2011, pp. 3111.
[26] K. Mašek, J. Beran, V. Matolín, "RHEED study of the growth of cerium oxide on Cu (1 1 1)" Applied Surface Science, Vol. 259, 2012, pp. 34.
[27] T. Montini, M. Melchionna, M. Monai, P. Fornasiero, "Fundamentals and catalytic applications of CeO2-based materials" Chemical reviews, Vol. 116, 2016, pp. 5987.
[28] B.C. Nelson, M.E. Johnson, M.L. Walker, K.R. Riley, C.M. Sims, "Antioxidant cerium oxide nanoparticles in biology and medicine" Antioxidants, Vol. 5, 2016, pp. 15.
[29] C. Walkey, S. Das, S. Seal, J. Erlichman, K. Heckman, L. Ghibelli, E. Traversa, J.F. McGinnis, W.T. Self, "Catalytic properties and biomedical applications of cerium oxide nanoparticles" Environmental Science: Nano, Vol. 2, 2015, pp. 33.
[30] K.A. Ledwa, L. Kępiński, "Dispersion of ceria nanoparticles on γ-alumina surface functionalized using long chain carboxylic acids" Applied Surface Science, Vol. 400, 2017, pp. 212.
[31] S. Ranganatha, T. Venkatesha, K. Vathsala, "Electrochemical studies on Zn/nano-CeO2 electrodeposited composite coatings" Surface and Coatings Technology, Vol. 208, 2012, pp. 64.
[32] J. Huiming, S. Jiang, L. Zhang, "Structural characterization and corrosive property of Ni-P/CeO2 composite coating" Journal of Rare Earths, Vol. 27, 2009, pp. 109.
[33] W.-c. Sun, J.-M. Xu, Y. Wang, F. Guo, Z.-W. Jia, "Effect of Cerium Oxide on Morphologies and Electrochemical Properties of Ni-WP Coating on AZ91D Magnesium" Journal of Materials Engineering and Performance, Vol. 26, 2017, pp. 5753.
[34] L. Ecco, M. Fedel, A. Ahniyaz, F. Deflorian, "Influence of polyaniline and cerium oxide nanoparticles on the corrosion protection properties of alkyd coating" Progress in Organic Coatings, Vol. 77, 2014, pp. 2031.
[35] E. Banczek, P. Rodrigues, I. Costa, "The effects of niobium and nickel on the corrosion resistance of the zinc phosphate layers" Surface and Coatings Technology, Vol. 202, 2008, pp.
[36] N. Rezaee, M. Attar, B. Ramezanzadeh, "Studying corrosion performance, microstructure and adhesion properties of a room temperature zinc phosphate conversion coating containing Mn2+ on mild steel" Surface and Coatings Technology, Vol. 236, 2013, pp. 361.
[37] F. Saberi, B.S. Boroujeny, A. Doostmohamdi, A.R. Baboukani, M. Asadikiya, "Electrophoretic deposition kinetics and properties of ZrO2 nano coatings" Materials Chemistry and Physics, Vol. 213, 2018, pp. 444.
[38] A. Standard, "Zeta potential of colloids in water and waste water" ASTM Standard D, Vol., 1985, pp. 4187.
[39] A. KozŁowski, "Dry friction of manganese phosphate coatings on steel and cast iron" Electrodeposition and Surface Treatment, Vol. 2, 1974, pp. 109.
[40] K. Chandrasekaran, S.N. TS Nellaiappan, R. Kulandaivelu, M.H. Lee, "Improving the reactivity and receptivity of alloy and tool steels for phosphate conversion coatings: role of surface mechanical attrition treatment" Industrial & Engineering Chemistry Research, Vol. 53, 2014, pp. 20124.
[41] L. Qihai, L. Zili, Z. Xinhua, L. Cuijin, D. Jiao, "Hydrogen production by steam reforming of ethanol over copper doped Ni/CeO2 catalysts" Journal of Rare Earths, Vol. 29, 2011, pp. 872.
[42] R. Pérez-Hernández, Catalytic Ni/CeO 2 Nanorods and Ag/CeO 2 Nanotubes for Hydrogen Production by Methanol Reforming, Advanced Catalytic Materials: Current Status and Future Progress, Springer2019, pp. 167-190.
[43] M. Tamilselvi, P. Kamaraj, M. Arthanareeswari, S. Devikala, "Nano zinc phosphate coatings for enhanced corrosion resistance of mild steel" Applied Surface Science, Vol. 327, 2015, pp. 218.
[44] M. Manna, A. Shah, S. Kulkarni, "Development of phosphate coating on the surface of TMT rebar: an option to study the effect of n-SiO2 as an additive" Ironmaking & Steelmaking, Vol. 44, 2017, pp. 666.
[45] D.B. Freeman, phosphating and metal pre-treatment: a guide to modern processes and practice, Woodhead-Faulkner, Cambridge, 1986.
[46] R. De Levie, "The influence of surface roughness of solid electrodes on electrochemical measurements" Electrochimica Acta, Vol. 10, 1965, pp. 113.
