Mechanical and Chemical Properties of Zn-Ni-Al2O3 Nanocomposite Coatings
Zn alloy and composite coatings are widely used in
buildings and structures, automobile and fasteners industries to
protect steel component from corrosion. In this paper, Zn-Ni-Al2O3
nanocomposite coatings were electrodeposited on mild steel using a
novel sol enhanced electroplating method. In this method, transparent
Al2O3 sol was added into the acidic Zn-Ni bath to produced Zn-Ni-
Al2O3 nanocomposite coatings. The effect of alumina sol on the
electrodeposition process, and coating properties was investigated
using cyclic voltammetry, XRD, ESEM and Tafel test. Results from
XRD tests showed that the structure of all coatings was single γ-
Ni5Zn21 phase. Cyclic voltammetry results showed that the
electrodeposition overpotential was lower in the presence of alumina
sol in the bath, and caused the reduction potential of Zn-Ni to shift to
more positive values. Zn-Ni-Al2O3 nanocomposite coatings produced
more uniform and compact deposits, with fine grained microstructure
when compared to Zn-Ni coatings. The corrosion resistance of Zn-Ni
coatings was improved significantly by incorporation of alumina
nanoparticles into the coatings.
[1] Boonyongmaneerat Y, Saenapitak S, Saengkiettiyut K. Reverse pulse
electrodeposition of Zn–Ni alloys from a chloride bath. J Alloys
Compounds. 2009 11/13;487(1–2):479-82.
[2] Abou-Krisha MM. Effect of pH and current density on the
electrodeposition of Zn–Ni–Fe alloys from a sulfate bath. Journal of
Coatings Technology and Research:1-9.
[3] Blejan D, Bogdan D, Pop M, Pop AV, Muresan LM. Structure,
morphology and corrosion resistance of Zn-Ni-TiO2 composite coatings.
Optoelectronics and Advanced Materials, Rapid Communications.
2011;5(1):25-9.
[4] Zheng H, An M. Electrodeposition of Zn–Ni–Al2O3 nanocomposite
coatings under ultrasound conditions. J Alloys Compounds. 2008
7/14;459(1–2):548-52.
[5] B.M. Praveen1 and T. V. Venkatesha2. Electrodeposition and Corrosion
Resistance Properties of Zn-Ni/TiO2 Nano composite Coatings.
International Journal of Electrochemistry. 2011;2011.
[6] Wang W, Hou F, Wang H, Guo H. Fabrication and characterization of
Ni–ZrO2 composite nano-coatings by pulse electrodeposition. Scr
Mater. 2005;53(5):613-8.
[7] Oberle R, Scanlon M, Cammarata R, Searson P. Processing and
hardness of electrodeposited Ni/Al2O3 nanocomposites. Appl Phys Lett.
1995;66(1):19-21.
[8] Yang Y, Chen W, Zhou C, Xu H, Gao W. Fabrication and
characterization of electroless Ni–P–ZrO2 nano-composite coatings.
Appl Nanosci. 2011 2011/05/01;1(1):19-26.
[9] Chen W, He Y, Gao W. Electrodeposition of sol-enhanced
nanostructured Ni-TiO2 composite coatings. Surface and Coatings
Technology. 2010 4/25;204(15):2487-92.
[10] Chen W, He Y, Gao W. Synthesis of Nanostructured Ni–TiO2
Composite Coatings by Sol-Enhanced Electroplating. J Electrochem
Soc. 2010;157(8):E122-8.
[11] Gomes A, Almeida I, Frade T, Tavares AC. Stability of Zn-Ni-TiO 2
and Zn-TiO 2 nanocomposite coatings in near-neutral sulphate solutions.
Journal of Nanoparticle Research. 2012;14(2).
[12] Gomes A, Almeida I, Frade T, Tavares AC. Zn-TiO 2 and ZnNi-TiO 2
nanocomposite coatings: Corrosion behaviour; 2010 (cited 17 September
2012).
[13] Tulio PC, Rodrigues SEB, Carlos IA. The influence of SiC and Al2O3
micrometric particles on the electrodeposition of ZnNi films and the
obtainment of ZnNi–SiC and ZnNi–Al2O3 electrocomposite coatings
from slightly acidic solutions. Surface and Coatings Technology. 2007
11/15;202(1):91-9.
[14] Casanova T, Soto F, Eyraud M, Crousier J. Hydrogen absorption during
zinc plating on steel. Corros Sci. 1997 3;39(3):529-37.
[15] Abou-Krisha M, Assaf F, Toghan A. Electrodeposition of Zn–Ni alloys
from sulfate bath. Journal of Solid State Electrochemistry.
2007;11(2):244-52.
[16] Benea L, Bonora PL, Borello A, Martelli S, Wenger F, Ponthiaux P, et
al. Composite electrodeposition to obtain nanostructured coatings. J
Electrochem Soc. 2001;148(7):C461-5.
[17] Hegde AC, Venkatakrishna K, Eliaz N. Electrodeposition of Zn–Ni, Zn–
Fe and Zn–Ni–Fe alloys. Surface and Coatings Technology. 2010
12/25;205(7):2031-41.
[18] Elkhatabi F, Benballa M, Sarret M, Müller C. Dependence of coating
characteristics on deposition potential for electrodeposited Zn–Ni alloys.
Electrochim Acta. 1999 1;44(10):1645-53.
[19] Damjanovic A, Setty T, Bockris J. Effect of Crystal Plane on the
Mechanism and the Kinetics of Copper Electrocrystallization. J
Electrochem Soc. 1966;113(5):429-40.
[20] praveen BM, Venkatesha TV. Electrodeposition and properties of Zn–
Ni–CNT composite coatings. J Alloys Compounds. 2009 8/12;482(1–
2):53-7.
[21] Praveen BM, Venkatesha TV. Electrodeposition and properties of Znnanosized
TiO2 composite coatings. Appl Surf Sci. 2008
2/15;254(8):2418-24.
[22] Praveen BM, Venkatesha TV, Naik YA, Prashantha K. Corrosion
behavior of Zn-TiO2 composite coating. Synthesis and Reactivity in
Inorganic, Metal-Organic and Nano-Metal Chemistry. 2007;37(6):461-5.
[1] Boonyongmaneerat Y, Saenapitak S, Saengkiettiyut K. Reverse pulse
electrodeposition of Zn–Ni alloys from a chloride bath. J Alloys
Compounds. 2009 11/13;487(1–2):479-82.
[2] Abou-Krisha MM. Effect of pH and current density on the
electrodeposition of Zn–Ni–Fe alloys from a sulfate bath. Journal of
Coatings Technology and Research:1-9.
[3] Blejan D, Bogdan D, Pop M, Pop AV, Muresan LM. Structure,
morphology and corrosion resistance of Zn-Ni-TiO2 composite coatings.
Optoelectronics and Advanced Materials, Rapid Communications.
2011;5(1):25-9.
[4] Zheng H, An M. Electrodeposition of Zn–Ni–Al2O3 nanocomposite
coatings under ultrasound conditions. J Alloys Compounds. 2008
7/14;459(1–2):548-52.
[5] B.M. Praveen1 and T. V. Venkatesha2. Electrodeposition and Corrosion
Resistance Properties of Zn-Ni/TiO2 Nano composite Coatings.
International Journal of Electrochemistry. 2011;2011.
[6] Wang W, Hou F, Wang H, Guo H. Fabrication and characterization of
Ni–ZrO2 composite nano-coatings by pulse electrodeposition. Scr
Mater. 2005;53(5):613-8.
[7] Oberle R, Scanlon M, Cammarata R, Searson P. Processing and
hardness of electrodeposited Ni/Al2O3 nanocomposites. Appl Phys Lett.
1995;66(1):19-21.
[8] Yang Y, Chen W, Zhou C, Xu H, Gao W. Fabrication and
characterization of electroless Ni–P–ZrO2 nano-composite coatings.
Appl Nanosci. 2011 2011/05/01;1(1):19-26.
[9] Chen W, He Y, Gao W. Electrodeposition of sol-enhanced
nanostructured Ni-TiO2 composite coatings. Surface and Coatings
Technology. 2010 4/25;204(15):2487-92.
[10] Chen W, He Y, Gao W. Synthesis of Nanostructured Ni–TiO2
Composite Coatings by Sol-Enhanced Electroplating. J Electrochem
Soc. 2010;157(8):E122-8.
[11] Gomes A, Almeida I, Frade T, Tavares AC. Stability of Zn-Ni-TiO 2
and Zn-TiO 2 nanocomposite coatings in near-neutral sulphate solutions.
Journal of Nanoparticle Research. 2012;14(2).
[12] Gomes A, Almeida I, Frade T, Tavares AC. Zn-TiO 2 and ZnNi-TiO 2
nanocomposite coatings: Corrosion behaviour; 2010 (cited 17 September
2012).
[13] Tulio PC, Rodrigues SEB, Carlos IA. The influence of SiC and Al2O3
micrometric particles on the electrodeposition of ZnNi films and the
obtainment of ZnNi–SiC and ZnNi–Al2O3 electrocomposite coatings
from slightly acidic solutions. Surface and Coatings Technology. 2007
11/15;202(1):91-9.
[14] Casanova T, Soto F, Eyraud M, Crousier J. Hydrogen absorption during
zinc plating on steel. Corros Sci. 1997 3;39(3):529-37.
[15] Abou-Krisha M, Assaf F, Toghan A. Electrodeposition of Zn–Ni alloys
from sulfate bath. Journal of Solid State Electrochemistry.
2007;11(2):244-52.
[16] Benea L, Bonora PL, Borello A, Martelli S, Wenger F, Ponthiaux P, et
al. Composite electrodeposition to obtain nanostructured coatings. J
Electrochem Soc. 2001;148(7):C461-5.
[17] Hegde AC, Venkatakrishna K, Eliaz N. Electrodeposition of Zn–Ni, Zn–
Fe and Zn–Ni–Fe alloys. Surface and Coatings Technology. 2010
12/25;205(7):2031-41.
[18] Elkhatabi F, Benballa M, Sarret M, Müller C. Dependence of coating
characteristics on deposition potential for electrodeposited Zn–Ni alloys.
Electrochim Acta. 1999 1;44(10):1645-53.
[19] Damjanovic A, Setty T, Bockris J. Effect of Crystal Plane on the
Mechanism and the Kinetics of Copper Electrocrystallization. J
Electrochem Soc. 1966;113(5):429-40.
[20] praveen BM, Venkatesha TV. Electrodeposition and properties of Zn–
Ni–CNT composite coatings. J Alloys Compounds. 2009 8/12;482(1–
2):53-7.
[21] Praveen BM, Venkatesha TV. Electrodeposition and properties of Znnanosized
TiO2 composite coatings. Appl Surf Sci. 2008
2/15;254(8):2418-24.
[22] Praveen BM, Venkatesha TV, Naik YA, Prashantha K. Corrosion
behavior of Zn-TiO2 composite coating. Synthesis and Reactivity in
Inorganic, Metal-Organic and Nano-Metal Chemistry. 2007;37(6):461-5.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:70497", author = "Soroor Ghaziof and Wei Gao", title = "Mechanical and Chemical Properties of Zn-Ni-Al2O3 Nanocomposite Coatings", abstract = "Zn alloy and composite coatings are widely used in
buildings and structures, automobile and fasteners industries to
protect steel component from corrosion. In this paper, Zn-Ni-Al2O3
nanocomposite coatings were electrodeposited on mild steel using a
novel sol enhanced electroplating method. In this method, transparent
Al2O3 sol was added into the acidic Zn-Ni bath to produced Zn-Ni-
Al2O3 nanocomposite coatings. The effect of alumina sol on the
electrodeposition process, and coating properties was investigated
using cyclic voltammetry, XRD, ESEM and Tafel test. Results from
XRD tests showed that the structure of all coatings was single γ-
Ni5Zn21 phase. Cyclic voltammetry results showed that the
electrodeposition overpotential was lower in the presence of alumina
sol in the bath, and caused the reduction potential of Zn-Ni to shift to
more positive values. Zn-Ni-Al2O3 nanocomposite coatings produced
more uniform and compact deposits, with fine grained microstructure
when compared to Zn-Ni coatings. The corrosion resistance of Zn-Ni
coatings was improved significantly by incorporation of alumina
nanoparticles into the coatings.", keywords = "Zn-Ni-Al2O3 composite coatings, steel, sol-enhanced
electroplating, corrosion resistance.", volume = "9", number = "8", pages = "997-5", }
