Corrosion and heat treatment studies are essential to predict the performance and sustainability of the coatings in harsh environments, such as the oil and gas industries. In this study, nickel phosphorus (NiP)–titanium (Ti) nanocomposite coatings (NiP-Ti nanoparticles (TNPs)), containing various concentrations of Ti nanoparticles (TNPs) were deposited on high strength low alloy (HSLA) steel through electroless deposition processing. The concentrations of 0.25, 0.50 and 1.0 g/L TNPs were dispersed in the electroless bath, to obtain NiP-TNPs nanocomposite coatings comprising different Ti contents. Further, the effect of TNPs on the structural, mechanical, corrosion, and heat treatment performance of NiP coatings was thoroughly studied to illustrate the role of TNPs into the NiP matrix. Field emission scanning electron microscope (FESEM) and energy dispersive spectroscopy (EDX) results confirm the successful incorporation of TNPs into the NiP matrix. A substantial improvement in the mechanical response of the NiP matrix was noticed with an increasing amount of TNPs, which reached to its ultimate values (hardness 675 Hv, modulus of elasticity 18.26 GPa, and stiffness 9.02 kN/m) at NiP-0.5TNPs coatings composition. Likewise, the electrochemical impedance spectroscopy measurements confirmed a tremendous increase in the corrosion inhibition efficiency of the NiP coatings with an increasing amount of TNPs, reaching ~96.4% at a composition of NiP-0.5TNPs. In addition, the NiP-TNPs nanocomposite coatings also unveiled better performance after heat treatment than NiP coatings, due to the presence of TNPs into the NiP matrix and the formation of more stable (heat resistant) phases, such as Ni3P, Ni3Ti, NiO, etc., during the subsequent processing.
In the present study, the effect of concentration of titanium carbide (TiC) particles on the structural, mechanical, and electrochemical properties of Ni–P composite coatings was investigated. Various amounts of TiC particles (0, 0.5, 1.0, 1.5, and 2.0 g L−1) were co-electrodeposited in the Ni–P matrix under optimized conditions and then characterized by employing various techniques. The structural analysis of prepared coatings indicates uniform, compact, and nodular structured coatings without any noticeable defects. Vickers microhardness and nanoindentation results demonstrate the increase in the hardness with an increasing amount of TiC particles attaining its terminal value (593HV100) at the concentration of 1.5 g L−1. Further increase in the concentration of TiC particles results in a decrease in hardness, which can be ascribed to their accumulation in the Ni–P matrix. The electrochemical results indicate the improvement in corrosion protection efficiency of coatings with an increasing amount of TiC particles reaching to ~ 92% at 2.0 g L−1, which can be ascribed to a reduction in the active area of the Ni–P matrix by the presence of inactive ceramic particles. The favorable structural, mechanical, and corrosion protection characteristics of Ni–P–TiC composite coatings suggest their potential applications in many industrial applications.
Superior corrosion
resistance along with higher mechanical performance
is becoming a primary requirement to decrease operational costs in
the industries. Nickel-based phosphorus coatings have been reported
to show better corrosion resistance properties but suffer from a lack
of mechanical strength. Zirconium carbide nanoparticles (ZCNPs) are
known for promising hardness and unreactive behavior among variously
reported reinforcements. The present study focuses on the synthesis
and characterization of novel Ni-P-ZrC nanocomposite coatings developed
through the electrodeposition technique. Successful coelectrodeposition
of ZCNPs without any observable defects was carried out utilizing
a modified Watts bath and optimized conditions. For a clear comparison,
structural, surface, mechanical, and electrochemical behaviors of
Ni-P and Ni-P-ZrC nanocomposite coatings containing 0.75 g/L ZCNPs
were thoroughly investigated. The addition of ZCNPs has a considerable
impact on the properties of Ni-P coatings. Enhancement in the mechanical
properties (microhardness, nanoindentation, wear, and erosion) is
observed due to reinforcement of ZCNPs in the Ni-P matrix, which can
be attributed to mainly the dispersion hardening effect. Furthermore,
corrosion protection efficiency (PE%) of the Ni-P matrix was enhanced
by the incorporation of ZCNPs from 71 to 85.4%. The Ni-P-ZrC nanocomposite
coatings provide an exciting option for their utilization in the automotive,
electronics, aerospace, oil, and gas industry.
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