Abstract
Electroless nickel-phosphorous (NiP) coatings were produced on low carbon steel substrates for a total plating time of 3 h. Different preparation modalities were pursued. Multilayered coatings were produced by stacking three layers of the same composition by successive electroless plating with rinsing steps in between. On the other hand, coatings termed ‘monolayered’ for the sake of comparison were deposited by one step electroless process, with and without undergoing bath replenishment of the electrolyte during plating. All the samples were subjected to thermal annealing at 400 °C for 1 h under argon atmosphere.The results show that the multilayer approach prevents crack propagation in the as-deposited coatings because the interfaces between layers block the advance of defects. Bath replenishment during monolayered coatings production creates pseudo-interfaces similar to those of the multilayered case but they are ineffective in terms of corrosion protection. Un-replenishment of the electrolyte promotes a change in the coating's microstructure from lamellar to columnar which severely worsens their performance. Upon annealing, the presence of interfaces, along with the recrystallization of the metallic matrix, promotes an upgrading of the corrosion performance of the multi-layered coatings. The corrosion products spread laterally at the interface where they stockpile. At a certain point, the accumulation of these by-products provokes the exfoliation of the outermost layer exposing the layer underneath to the corrosive media, thereby delaying the advancement of the corrosion attack. The results of this study highlight the importance of the plating approach selection, as well as the need for proper electrolyte maintenance during the production of high-performance electroless coatings.
Highlights
Electroless nickel plating was firstly reported in the seminal paper by Brenner and Riddell, published in 1946 [1]
A priori, one would expect to find more defects on the ur-monolayered coating produced without electrolyte replenishment because the working piece remains in the electrolyte for longer plating time compared to the multilayer case
Results indicate that The Er and H values are very similar among the three samples, in agreement with the similar crystal structure and crystallite size measured from XRD diffraction despite the differences revealed by the cross-section field-emission scanning electron microscopy (FESEM) images. These results indicates that the mechanical properties are not sensitive to the change from lamellar to columnar growth revealed by the cross-section FESEM images microstructure in the coatings fabricated using the different synthetic approaches, likely due to the very local nature of the indentations performed
Summary
Electroless nickel plating was firstly reported in the seminal paper by Brenner and Riddell, published in 1946 [1]. Based on their excellent mechanical properties and corrosion resistance, it has become one of the preferred engineering solutions for high demanding applications [2]. Hexavalent hard chromium deposits stand out for their excellent mechanical properties, including hardness and wear, as well as their superior corrosion resistance in functional applications [5]. Among all the metals that can be electrolessly plated, nickel and its alloys represent 95% of all the industrial applications, being hypophosphite being the most used reducing agent [9]. The properties of nickel-phosphorous (NiP) coatings greatly depend on the phosphorous content in the alloy. High phosphorous coatings (10-14 wt.% P) present superior corrosion resistance but poor mechanical properties. Medium P content coatings (6-9 wt.% P) offer a good compromise over the formers in terms of mechanical properties and corrosion resistance [10]
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