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I. Valov, D. Stoychev, T. Marinova (2002)
Study of the kinetics of processes during electrochemical deposition of zirconia from nonaqueous electrolytesElectrochimica Acta, 47
International Journal of Electrochemical Science, 6
S. Ranganatha, T. Venkatesha, K. Vathsala (2012)
Process and properties of electroless Ni-Cu-P-ZrO2 nanocomposite coatingsMaterials Research Bulletin, 47
B. Szczygieł, Małgorzata Kołodziej (2005)
Composite Ni/Al2O3 coatings and their corrosion resistanceElectrochimica Acta, 50
M. Sri̇vastava, A. Srinivasan, V. Grips (2012)
Influence of Zirconia Incorporation on the Mechanical and Chemical Properties of Ni-Co AlloysAmerican Journal of Materials Science, 1
S. Kim, J. Kim, J. Yu, T. Lee (2004)
Residual stress and interfacial reaction of the electroplated Ni-Cu alloy under bump metallurgy in the flip-chip solder jointJournal of Electronic Materials, 33
E. Chassaing, K. Quang, R. Wiart (1987)
Mechanism of copper-nickel alloy electrodepositionJournal of Applied Electrochemistry, 17
A. Aal, Z. Zaki, Z. Hamid (2007)
Novel composite coatings containing (TiC–Al2O3) powderMaterials Science and Engineering A-structural Materials Properties Microstructure and Processing, 447
M. Vaezi, S. Sadrnezhaad, L. Nikzad (2008)
Electrodeposition of Ni–SiC nano-composite coatings and evaluation of wear and corrosion resistance and electroplating characteristicsColloids and Surfaces A: Physicochemical and Engineering Aspects, 315
H. Hassan, Z. Hamid (2011)
Electrodeposited Ni–Cr2O3 nanocomposite anodes for ethanol electrooxidationInternational Journal of Hydrogen Energy, 36
P. Baghery, M. Farzam, A. Mousavi, M. Hosseini (2010)
Ni–TiO2 nanocomposite coating with high resistance to corrosion and wearSurface & Coatings Technology, 204
Sam Zhang, Deen Sun, Y. Fu, H. Du (2005)
Toughening of hard nanostructural thin films: a critical reviewSurface & Coatings Technology, 198
Wei Wang, F. Hou, Hui Wang, Hetong Guo (2005)
Fabrication and characterization of Ni–ZrO2 composite nano-coatings by pulse electrodepositionScripta Materialia, 53
H. Simunkova, P. Pessenda-Garcia, J. Wosik, P. Angerer, H. Kronberger, G. Nauer (2009)
The fundamentals of nano- and submicro-scaled ceramic particles incorporation into electrodeposited nickel layers: Zeta potential measurementsSurface & Coatings Technology, 203
M. Alper, Hakan Köçkar, M. Safak, M. Baykul (2008)
Comparison of Ni–Cu alloy films electrodeposited at low and high pH levelsJournal of Alloys and Compounds, 453
L. Benea, P. Bonora, A. Borello, S. Martelli (2001)
Wear corrosion properties of nano-structured SiC–nickel composite coatings obtained by electroplatingWear, 249
D. Stoychev, J. Ikonomov, K. Robinson, P. Stefanov, M. Stoycheva, T. Marinova (2000)
Surface modification of porous zirconia layers by electrochemical deposition of small amounts of Cu or Co and Co + CuSurface and Interface Analysis, 30
Z. Hamid (2001)
Thermodynamic parameters of electrodeposition of Zn‐Co‐TiO2 composite coatingsAnti-corrosion Methods and Materials, 48
E. Setare, K. Raeissi, M. Golozar, M. Fathi (2009)
The structure and corrosion barrier performance of nanocrystalline zirconia electrodeposited coatingCorrosion Science, 51
M. Datta, D. Landolt (2000)
Fundamental aspects and applications of electrochemical microfabricationElectrochimica Acta, 45
M. Ishikawa, H. Enomoto, M. Matsuoka, C. Iwakura (1994)
Effect of tetraborate ions on electrodeposition of nickel—copper alloy from a pyrophosphate bathElectrochimica Acta, 39
S. Yuan, S. Pehkonen (2007)
Surface characterization and corrosion behavior of 70/30 Cu-Ni alloy in pristine and sulfide-containing simulated seawaterCorrosion Science, 49
M. Khalil, T. Eldin, H. Hassan, Kh. El-sayed, Z. Hamid (2015)
Electrodeposition of Ni–GNS–TiO2 nanocomposite coatings as anticorrosion film for mild steel in neutral environmentSurface & Coatings Technology, 275
A. Robin, J. Santana, A. Sartori (2011)
Co-electrodeposition and characterization of Cu–Si3N4 composite coatingsSurface & Coatings Technology, 205
Xiaodong Li, B. Bhushan (2002)
A Review of Nanoindentation Continuous Stiffness Measurement Technique and Its ApplicationsMaterials Characterization, 48
International Journal of Hydrogen Energy, 3
W. Wang, H. Guo, J. Gao, X. Dong, Q. Qin (2000)
XPS, UPS and ESR studies on the interfacial interaction in Ni-ZrO2 composite platingJournal of Materials Science, 35
PurposeThe purpose of this study is to investigate the effect of the incorporated zirconia (ZrO2) nanoparticles on the performance of the deposited layer Ni–Cu alloy on steel sheet.Design/methodology/approachThe aim was to produce Ni–Cu–ZrO2 nanocomposite coatings by electrodeposition technique and estimate the influence of ZrO2 nanoparticles on the performance of Ni–Cu alloy. The surface morphologies and chemical compositions of the deposited layers were assessed using scanning electron microscopy and energy-dispersive X-ray analysis, respectively. Nanoindentation was used as a well-advanced technique for measuring microhardness and Young’s modulus values of different coatings. The corrosion resistance in 3.5 per cent NaCl solution of electrodeposited films has been investigated.FindingsThe main conclusion is that the surface morphologies of Ni–Cu–ZrO2 nanocomposite coatings were fine granular compared with Ni–Cu alloy. The corrosion behavior illustrated that the incorporation of ZrO2 nanoparticles with Ni–Cu film improved the corrosion resistance. Significant improvement was also demonstrated in the hardness of nanocomposite coatings.Social implicationsThe optimized industrial use of steel-coated Ni–Cu alloy with super properties. Consequently, a social benefit can be associated with the reduction in the corrosion rate and increases the microhardness and Young’s modulus.Originality/valueThe results presented in this work are an insight into understanding the incorporation of ceramic reinforcement with metal or alloy films (matrix) on carbon steel using the electrodeposition technique. The development of corrosion resistance of Ni–Cu alloys has been considered as a promising behavior. In this work, a consistent assessment of the results achieved on laboratory scale has been conducted.
Anti-Corrosion Methods and Materials – Emerald Publishing
Published: May 2, 2017
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