Electrodeposition and properties of Ni-B/SiC nanocomposite coatings

Ni-B/SiC composite coatings were electrodeposited using trimethylamine borane as a boron source. The effects of bath composition and operating parameters on the microstructure and properties of the composite coatings were investigated. The results show that Ni-B/SiC composite coating exhibits unifor...

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Published inSurface engineering Vol. 35; no. 2; pp. 110 - 120
Main Authors Li, B. S., Huan, Y. X., Luo, H., Zhang, W. W.
Format Journal Article
LanguageEnglish
Published London, England Taylor & Francis 01.02.2019
SAGE Publications
Subjects
corrosion resistance
Electrodeposition
microhardness
Ni-B/SiC composite coating
wear resistance
Electrodeposition
microhardness
Ni–B/SiC composite coating
corrosion resistance
wear resistance
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Abstract Ni-B/SiC composite coatings were electrodeposited using trimethylamine borane as a boron source. The effects of bath composition and operating parameters on the microstructure and properties of the composite coatings were investigated. The results show that Ni-B/SiC composite coating exhibits uniform structure with a desirable interface. Incorporation of SiC particles led to a significant increase in hardness. Both boron and SiC content in the coating increases initially and then decreases as the current density increased. Incorporation of inert SiC particles also enhanced their corrosion resistance, which attributed to the dense structure, barrier effect and the reduction in the active surface area of Ni-B matrix. XPS analysis indicated that the as-deposited coating contains metallic nickel, oxide or hydroxide nickel, and the SiC particles. Owing to dispersion hardening of the added SiC particles and the reduction in the active surface area of Ni-B matrix, Ni-B/SiC composite coating shows superior anti-corrosion and wear resistance.
AbstractList Ni-B/SiC composite coatings were electrodeposited using trimethylamine borane as a boron source. The effects of bath composition and operating parameters on the microstructure and properties of the composite coatings were investigated. The results show that Ni-B/SiC composite coating exhibits uniform structure with a desirable interface. Incorporation of SiC particles led to a significant increase in hardness. Both boron and SiC content in the coating increases initially and then decreases as the current density increased. Incorporation of inert SiC particles also enhanced their corrosion resistance, which attributed to the dense structure, barrier effect and the reduction in the active surface area of Ni-B matrix. XPS analysis indicated that the as-deposited coating contains metallic nickel, oxide or hydroxide nickel, and the SiC particles. Owing to dispersion hardening of the added SiC particles and the reduction in the active surface area of Ni-B matrix, Ni-B/SiC composite coating shows superior anti-corrosion and wear resistance.
Author Huan, Y. X.
Luo, H.
Zhang, W. W.
Li, B. S.
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Issue 2
Keywords Electrodeposition
microhardness
Ni–B/SiC composite coating
corrosion resistance
wear resistance
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Snippet Ni-B/SiC composite coatings were electrodeposited using trimethylamine borane as a boron source. The effects of bath composition and operating parameters on...
Ni–B/SiC composite coatings were electrodeposited using trimethylamine borane as a boron source. The effects of bath composition and operating parameters on...
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informaworld
SourceType Enrichment Source
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StartPage 110
SubjectTerms corrosion resistance
Electrodeposition
microhardness
Ni-B/SiC composite coating
wear resistance
Title Electrodeposition and properties of Ni-B/SiC nanocomposite coatings
URI https://www.tandfonline.com/doi/abs/10.1080/02670844.2018.1474020
https://journals.sagepub.com/doi/full/10.1080/02670844.2018.1474020
Volume 35
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