Graphene-Reinforced Zn–Ni Alloy Composite Coating on Iron Substrates by Pulsed Reverse Electrodeposition and Its High Corrosion Resistance

Li, Sishi; Song, Gongsheng; Zhang, Yupeng; Fu, Qiang; Pan, Chunxu

doi:10.1021/acsomega.1c00977

Cited by 14 publications

(9 citation statements)

References 55 publications

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“…53 Moreover, hybridizing rGO with ZnO imparts enhancement in the dispersibility, and the enhancement in nucleation sites by rGO incorporation further results in the formation of coating with refined grain size and a compact microstructure. 54 The cross-sectional SEM study also confirms the formation of minimum pores and cracks in the 0.3 wt %-RGZ coating. However, the presence of agglomerated rGO− ZnO nanoparticles in 0.5 wt %-RGZ coating results in nonuniform dispersion and thereby reduces the coating hardness.…”

Section: Evaluation Of Microhardness and Adhesion Strength Of Rgz Coa...mentioning

confidence: 58%

“…The inherent ability of rGO to strengthen ceramics by improved physical adsorption that causes better particle–particle interaction is utilized in fabricating the hard coating . Moreover, hybridizing rGO with ZnO imparts enhancement in the dispersibility, and the enhancement in nucleation sites by rGO incorporation further results in the formation of coating with refined grain size and a compact microstructure . The cross-sectional SEM study also confirms the formation of minimum pores and cracks in the 0.3 wt %-RGZ coating.…”

Section: Resultsmentioning

confidence: 82%

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Multifunctional rGO–ZnO Composite Coatings with Enhanced Mechanical, Anticorrosion, and Antibacterial Characteristics for Practical Applications

Geethanjali,

Elias,

Bijimol

et al. 2023

ACS Appl. Eng. Mater.

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This paper reports the development of multifunctional rGO–ZnO composite (RGZ) coatings with enhanced mechanical, anticorrosion, and antibacterial characteristics for practical marine applications. The structure and composition of the RGZ composite coatings are tuned to achieve distinct and compact intermetallic alloy layers, leading to improved hardness, wear resistance, friction resistance, electrochemical stability, and antibacterial activity. 0.3 wt %-RGZ composite coating with the highest R ct value (367.8 Ω cm2) exhibits the least corrosion rate (0.75 mmpy) as compared to the other compositions of the developed coatings. All the RGZ composite coatings exhibit enhanced antibacterial activity in different bacterial suspensions selected for the present study (Escherichia coli, Bacillus subtilis, and seawater consortium), and the 0.3 wt %-RGZ composite coating is demonstrated to be suitable for marine applications with the lowest bacterial survivability (20.3%) in the seawater consortium. The electrochemical stability and anticorrosion performance of the 0.3 wt %-RGZ composite coating even after long-term exposure (28 days) to seawater consortium confirmed from the largest R ct value (1154.7 Ω cm2) and the least i corr value (223.4 μA/cm2) indicate its suitability for practical application with excellent reusability. The enhanced antibacterial activity of the 0.3 wt %-RGZ composite coating as compared to other compositions of RGZ coatings and bare-Zn coating is attributed to its three-level bacterial destruction capability by inducing damage to the bacterial cell wall through physical damage, penetration of Zn2+ ions, and the activity of the photogenerated reactive oxygen species (ROS). The enhanced antibacterial activity and excellent electrochemical stability with attractive anticorrosion performance of 0.3 wt %-RGZ composite coating even after long-term exposure (28 days) in different bacterial suspensions, especially in seawater consortium, confirm its suitability for practical applications.

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Section: Evaluation Of Microhardness and Adhesion Strength Of Rgz Coa...mentioning

confidence: 58%

Section: Resultsmentioning

confidence: 82%

Multifunctional rGO–ZnO Composite Coatings with Enhanced Mechanical, Anticorrosion, and Antibacterial Characteristics for Practical Applications

Geethanjali,

Elias,

Bijimol

et al. 2023

ACS Appl. Eng. Mater.

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“…It is possible that the incorporation of the nanocrystals in the coating results in a decrease in the active surface in contact with the corrosive solution, thus increasing the corrosion resistance of the coating 15 . As suggested in relation to the incorporation of graphene oxide 69 and silica nanoparticles 70 , it is also possible that the incorporation of nanocrystals hinders the diffusion of oxygen, thus inhibiting the reduction reaction with the consequent increase in corrosion resistance. By presenting a low level of electrical conductivity, it is also possible that nanocrystals, when uniformly dispersed in the coating, cause an increase in the resistance to current flow, in addition to promoting the distract of this current flow 44,71 .…”

Section: Effect Of the Addition Of Sisal Nanocrystals On The Corrosio...mentioning

confidence: 99%

Electrodeposited Zn-Ni-sisal Nanocrystals Composite Coatings - Morphology, Structure and Corrosion Resistance

Borges,

Koga,

Rigoli

et al. 2023

Mat. Res.

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Zn-Ni alloys have been used to decrease the corrosion rate of carbon steel substrates. These are used in applications such as bolt coatings, threaded parts, swift valves for gas pipelines, aircraft landing gear, brake system components and others. Zn-Ni coatings containing nanocrystals of cellulose (CNC) obtained from sisal fiber (Sif), a natural polymer, were manufactured using the electroplating technique. Obtaining the nanocrystals involved bleaching raw sisal fiber and then acid hydrolysis to extract the nanocrystal. The effect of the concentrations of the CNC-Sif (0% v/v, 2%v/v, 3%v/v, and 4%v/v) on the morphology and microstructure of the Zn-Ni coating was analyzed through Scanning Electron Microscopy (SEM), X-ray diffraction, and roughness measurements using confocal microscopy. The effect of the addition of CNC-Sif on the efficiency of galvanostatic deposition was analyzed. The corrosion rate through mass loss and electrochemical tests were also analyzed. The effect of adding CNC-SIF on coating microhardness investigated. This study show that the addition of nanocrystals alters the structure, the morphology, increases current efficiency and the corrosion resistance of the Zn-Ni coating and these effects are more significant with the addition of 2% v/v. The results obtained indicate that the addition of the CNC-Sif in the Zn-Ni coating is promising, because it reduces the energy consumed during the electrodeposition process in addition to increasing corrosion resistance of the Zn-Ni and the microhardness.

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“…These coatings involve the combination of different materials such as zinc, nickel, cobalt, tungsten, tin, graphene, CNT and many more to leverage their advantageous properties and create synergistic effects like enhancing the corrosion and wear resistance of the nanocomposite coatings. [2][3][4][5][6][7][8][9][10][11] Zinc, tungsten and graphene are among the materials that have gained significant attention for this purpose. Excellent corrosion resistance properties are known for zinc.…”

Section: Introductionmentioning

confidence: 99%

Investigation on tribological behaviour of co-deposited zinc, tungsten and graphene (ZnWG) nanocomposite coatings on low-carbon steel

Karthik,

Yoganandh,

Raveen

2023

Proceedings of the Institution of Mechanical Engineers, Part L:

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The protection of steel surfaces in industrial applications to improve their tribological behaviour using graphene-based nanocomposite coatings is a potential area for researchers to investigate. An attempt has been made to develop and compare the tribological properties of Zinc–tungsten (ZnW), Zinc–Tungsten with 0.25 wt.% of graphene (ZnWG 0.25 wt.%) and Zinc-Tungsten with 0.50 wt.% of graphene (ZnWG 0.50 wt.%) coatings on steel substrates with low-carbon content using the electroplating technique with pulse power supply. The electrolyte bath for pulsed electro-deposition was maintained as aqueous by involving zinc sulphate, sodium tungstate and citric acid. The experiments inferred that ZnWG 0.50 wt.% performed with better wear resistance due to its increased graphene content, contributing to the effective ductile load-bearing ability of the ZnW coating matrix. Grain size control and improved grain strength due to the presence of graphene in the ZnW matrix produced dislocation obstruction and displacement inhibition to create defect-free layered cauliflower morphology and contributed to ZnWG 0.50 wt.% exhibiting better corrosion resistance than the plain ZnW coating.

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Graphene-Reinforced Zn–Ni Alloy Composite Coating on Iron Substrates by Pulsed Reverse Electrodeposition and Its High Corrosion Resistance

Cited by 14 publications

References 55 publications

Multifunctional rGO–ZnO Composite Coatings with Enhanced Mechanical, Anticorrosion, and Antibacterial Characteristics for Practical Applications

Multifunctional rGO–ZnO Composite Coatings with Enhanced Mechanical, Anticorrosion, and Antibacterial Characteristics for Practical Applications

Electrodeposited Zn-Ni-sisal Nanocrystals Composite Coatings - Morphology, Structure and Corrosion Resistance

Investigation on tribological behaviour of co-deposited zinc, tungsten and graphene (ZnWG) nanocomposite coatings on low-carbon steel

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