Electrodeposition Process of Composite Ni-P+Ni(OH)2+PTFE Coatings

B. Łosiewicz; Magdalena Popczyk

doi:10.4028/www.scientific.net/SSP.228.108

Paper Titles

Electrodeposition Mechanism of Composite Coatings
p.65

Characteristics of the Galvanic Baths for Electrodeposition of Nickel Coatings Using the Hull Cell
p.79

The Role of Ni(II) Ion Adsorption onto TiO₂ in the Electrodeposition of Composite Ni-P+TiO₂ Coatings
p.89

Relaxation Characteristics of the Electrodeposition Process of Composite Ni-P+TiO₂+PTFE and Ni-P+Ni(OH)₂+PTFE Coatings
p.101

Electrodeposition Process of Composite Ni-P+Ni(OH)₂+PTFE Coatings
p.108

DC Current Electrodeposition of High Mo Content Ni-Mo Alloy Coatings from Alkaline Solutions
p.116

Electrodeposition of the Ni+MoS₂ Composite Electrocatalysts
p.125

Electrodeposition of the Ni-Mo+MoO₂ Composite Electrocoatings
p.132

Effect of Phosphorus on the Structure of Nickel Electrocoatings
p.141

HomeSolid State PhenomenaSolid State Phenomena Vol. 228Electrodeposition Process of Composite...

Electrodeposition Process of Composite Ni-P+Ni(OH)₂+PTFE Coatings

Abstract:

Co-deposition process of amorphous nickel and PTFE particles in the presence of Ni (OH)₂ carrier suspended in the bath by magnetic stirring, was investigated. Composite Ni-P+Ni (OH)₂+PTFE coatings and comparative Ni-P deposits, were electrodeposited on low carbon steel substrate under galvanostatic conditions at room temperature. The physical and chemical characterization of the coatings was carried out using X-Ray diffraction analysis and microanalysis, stereometric quantitative microscopy and atomic absorption spectroscopy. The optimum production conditions of the composite coatings based on the Ni-P matrix into which PTFE and Ni (OH)₂ components can be embedded uniformly, were found.

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Periodical:

Solid State Phenomena (Volume 228)

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108-115

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https://doi.org/10.4028/www.scientific.net/SSP.228.108

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Online since:

March 2015

Authors:

B. Łosiewicz*, Magdalena Popczyk

Keywords:

Amorphous Nickel, Composite Coatings, Electrodeposition, Ni(OH)₂ Carrier, PTFE

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