Browsing by Author "Flis, J."
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Item Metadata only Corrosion behaviour of sediment electro-codeposited Ni-Al2O3 composite coatings(Elsevier, 2014) Sun, Yong; Flis-Kabulska, I.; Flis, J.NieAl 2O3 composite coatings were produced by the sediment electro-codeposition (SECD) technique at various particle loadings and current densities. The submicron Al 2O3 particles were found to distribute uniformly in the coating, and 12e18 vol.% particles can be incorporated in the coating depending on deposition current density and particle loading in the plating bath. Electrochemical corrosion testing was conducted in 0.9 wt.% NaCl solution. The results show that the incorporation of Al 2O3 particles in the coating did not affect the general corrosion behaviour of the Ni coating. However, at higher anodic potentials approaching the breakdown potential and with prolonged polarization, the composite coatings showed deteriorated corrosion resistance in terms of increased anodic current density, reduced pitting potential and quicker breakdown of the passivefilm. The detrimental effects of Al 2O3 particle incorporation could be explained by the existence of numerous boundaries between the particles and the matrix, which would serve as active sites for anodic dissolution and micro-pit formation.Item Metadata only Corrosion characteristics of low temperature plasma carburised and nitrocarburised 316L stainless steel in sulphate-chloride solution(2013) Flis-Kabulska, I.; Sun, Yong; Flis, J.Item Metadata only Hydrogen evolution on plasma carburised nickel and effect of iron deposition from electrolyte in alkaline water electrolysis(Elsevier, 2015) Flis-Kabulska, I.; Flis, J.; Sun, Yong; Zakroczymski, T.Presence of carbon in electrodeposited nanocrystalline Ni-Fe-C cathodes renders a high electroactivity for hydrogen evolution reaction (HER) in hot alkaline solutions. In the present work carbon was introduced into nickel cathodes by plasma treatment in CH4 + H2 gas mixture at 47 0 C. Electrochemical measurements were carried out in the solution of 25 wt.% KO H (reagent p.a.) at 80 C. In some measurements the solution wa s pre-electrolysed to remove heavy metals. Carburisation resulted in a significant enhancement of catalytic activity of nickel for HER during short cathodic polarisation. Later, differences between the materials almost disappeared, evidently due to deposition of iron and of other heavy metals from the solution. Cathodes with iron deposits underwent an activation following anodic polarisation. It wa s proposed that the activating effect of iron can be associated with the formation of highly reactive iron during cathodic reduction of oxide species (probably Fe(OH)4 2 ). The activating effect of prior anodic polarisation can be due to the formation of large amounts of oxide species which can undergo the reduction to reactive iron.Item Metadata only Monitoring the near-surface pH to probe the role of nitrogen in corrosion behaviour of low-temperature plasma nitrided 316L stainless steel(Elsevier, 2013) Flis-Kabulska, I.; Sun, Yong; Flis, J.Item Open Access Plasma carburizing for improvement of Ni-Fe cathodes for alkaline water electrolysis(Elsevier, 2016-10-13) Flis-Kabulska, I.; Sun, Yong; Zakroczymski, T.; Flis, J.Electrodeposited Ni-Fe-C alloys have high electroactivity for hydrogen evolution reaction (HER) in alkaline water electrolysis. In the present work carbon was introduced into Ni and Ni–Fe alloys by plasma treatment in CH4+H2 gas mixture at 470 oC. Despite of a very low solubility of carbon in nickel, carbon entered into nickel to the depth of about 0.5 µm, formed about 2-µm thick carbide layer in high-Fe alloys, and increased hardness. Electrochemical measurements in 25 wt.% KOH at 80 oC showed that carburization resulted in an improvement of catalytic activity toward HER, especially of Ni and 1Ni-Fe. Carburization also increased the resistance to corrosion during cathodic polarisation and under open-circuit conditions. XPS surface analysis showed that after corrosion the oxide content was on carburized materials significantly lower than that on untreated materials. It is suggested that the enhanced electroactivity of plasma carburized cathodes is due mainly to the enlargement of the surface area of disintegrated material. A catalytic affect might also be exerted by carbon-metal particles.