Production and Characterization of Copper-Niobium Composite Electrocoatings

Alain Robin; Jorge Luiz Rosa; Messias Borges Silva

doi:10.4028/www.scientific.net/MSF.805.184

Paper Titles

Improving the Carbon Steel Surface Treatment Process
p.161

Effect of Different Dopants in Films TEOS/MPTS Used to Protect the Carbon Steel
p.167

Evaluation of the Current Modulation Effect on the Cathodic Efficacy during Copper Electroplating in Alkaline Medium
p.172

The Metallographic Technical Preparation Influence on the Zinc Hot Dip Deposited Layer Morphology
p.178

Production and Characterization of Copper-Niobium Composite Electrocoatings
p.184

Aluminum Coating Obtained through the Sol-Gel Method to Protect Metallic Surfaces against Corrosion
p.190

Effect of Aging Treatment on Inconel 718 Superalloy: Application in Elevated Temperatures
p.199

Laser Surface Treatment of SAE 4340 and 300M Steels
p.204

Influence of Aging Time on the Tensile Strenght of a Duplex Stainless Steel
p.210

HomeMaterials Science ForumMaterials Science Forum Vol. 805Production and Characterization of Copper-Niobium...

Production and Characterization of Copper-Niobium Composite Electrocoatings

Abstract:

Copper-niobium composite electrocoatings were obtained by co-electrodeposition in acidic copper sulfate bath containing suspended niobium particles. The amount of incorporated particles was evaluated using a Central Composite Design (CCD) with three factors of control (cathodic current density, stirring rate and particle concentration in the bath) at three levels each. A great influence of particle concentration was observed. The stirring rate also had influence but to a lower extent and the cathodic current density was the least significant factor. The combination, both cathodic current density and particle concentration at the highest levels and stirring rate at the lowest level, led to the highest amount of incorporated particles. The behavior was not linear between the high and low levels for all factors. The roughness of the composites was higher than the pure copper coatings and increased with increasing current density. The microhardness of the composite layers was higher than that of pure copper deposits obtained under the same conditions due to copper matrix grain refinement and increased with the increase of both current density and incorporated particle volume fraction.