Abstract:
Magnesium (Mg) and its alloys are being used as structural components in
industries because of their high strength-to-weight ratio and relatively high stiffness. A
shortcoming of Mg alloys is poor corrosion and wear resistance that have hindered its
widespread applications. Corrosion can be minimized by using high purity alloys, rapid
solidification, and surface treatment or coatings. Of these techniques, electroless nickelphosphorus
(EN) coating is one of the most effective methods to combat the problems.
The objective of this research is to understand the relationships of processing,
microstructure and properties of EN coatings on Mg alloys, and therefore to develop
uniform, well-adhered, pore-free EN based coatings.
In the first stage of the work, three types of EN coatings, namely, low, medium,
and high phosphorus, were deposited on Mg and its alloy substrates. In the second stage
of this research, EN coatings containing superfine Al2O3 particles and a novel plasma
electrolysis assisted EN plating processing were developed on Mg alloys. XRD, SEM,
TEM, EDX, XPS, and some corrosion and mechanical testing methods were
implemented to evaluate and characterize the above EN-based coatings. The effects of
various alloy substrates and plating bath parameters on coating deposition rate, porosity,
phosphorus content, and properties, were studied in detail. Furthermore, the effect of
post heat treatment on the properties of EN coatings was also investigated.
The results of this study show that the properties of EN coatings are directly
related to the phosphorus content and porosity of the coatings, and various Mg alloy
substrates. EN coatings with low phosphorus content are nano-crystalline, hard and
ductile. As a result, they have superior adhesion strength. EN coatings with medium
phosphorus content have an amorphous structure with better corrosion and wear
resistance. Especially, the medium phosphorus EN coatings produced by novel plasma
electrolysis assisted processes provide superior corrosion resistance and higher
adhesion strength. The novel EN technique is also an environmental friendly processing.
Direct high phosphorus EN coatings show the least kinetic coefficient of friction and
good wear resistance under dry sliding friction because of the self-lubricating nature of
phosphorus element. However, the porosity is severe within the direct high phosphorus
coatings, which is detrimental to its corrosion property. Adhesion strength and wear
resistance of EN alumina composite coating on Mg alloys are improved significantly. It
has also been demonstrated that the adhesion strength of EN on Mg alloys is strongly
II
related to several parameters including coating thickness, hardness, internal stress,
nucleation density, and the substrate’s chemical and physical nature.
In conclusion, this research has made good progress on producing a series of
uniform, well-adhered, and pore-free EN-based coatings through better understanding
of the relationships of processing, microstructure and properties. The EN-based
coatings can provide adequate corrosion and/or wear resistance to Mg and Mg alloys.