Elsevier

Metal Finishing

Volume 94, Issue 3, March 1996, Pages 35-36, 38-40
Metal Finishing

Feature
Properties of electrodeposited NiP-SiC composite coatings

https://doi.org/10.1016/0026-0576(96)84169-9Get rights and content

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  • Cited by (44)

    • Corrosion and wear behavior of an electroless Ni-P/nano-SiC coating on AZ31 Mg alloy obtained through environmentally-friendly conversion coating

      2020, Surface and Coatings Technology
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      The Phosphorous content in the NiP coating affects their structure and properties. High phosphorous results in amorphous structure which is characterized by notable corrosion properties, however their hardness and wear resistance were decreased in comparison with low P content NiP coatings [8]. Researchers attempted to boost and develop the coating's properties by plating composite electroless coatings.

    • Electrodeposition of Ni[sbnd]P composite coatings: A review

      2019, Surface and Coatings Technology
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      With suitable control of operating conditions, codeposition of SiC particles within a NiP matrix results in an increased hardness, improved corrosion and wear resistance and a lower coefficient of friction of the alloy against steel [56,57,73]. Reduced residual stress and eliminated surface cracking have also been reported, together with increased ductility [32,59,74]. Ni-P/SiC composites, however, can exhibit higher surface roughness than pure NiP alloy electrodeposits [75].

    • Effect of SiC particle size and heat-treatment on microhardness and corrosion resistance of NiP electrodeposited coatings

      2018, Journal of Alloys and Compounds
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      Incorporation of hard ceramic particles in the coating could be an alternative to heat-treatment as the hardening mechanism [12]. Several researchers have successfully codeposited WC, SiC, Si3N4 in Ni-P matrices [12–16]. Malfatti et al. [17] studied the effect of SiC addition on the corrosion behavior of NiP/SiC coatings.

    • The effect of processing gas on corrosion performance of electroless Ni-W-P coatings treated by laser

      2012, Surface and Coatings Technology
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      The as-plated coating exhibited a relatively sharp Ni (111) peak, indicating a mixed-structural nature of the coating, consisting of amorphous and nanocrystalline Ni phases, which agreed with the studies by some other investigators showing that the as-plated medium phosphorus coatings (6–9 wt. % P) consisted of mixed crystalline and amorphous microstructures [24]. In addition, it was noticed that there was no reflection from tungsten or any tungsten compound in both cases, suggesting that W was a solute addition of Ni-P electroless deposits.

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