The effect of electrolyte concentration on the microdischarge behaviour during plasma electrolytic oxidation (PEO) on aluminium and titanium
POSTER
Abstract
The production of oxide-ceramic coatings on light metals aluminium, magnesium and titanium can be achieved by plasma electrolytic oxidation (PEO). High corrosion resistance and a good adhesion of the coating to the substrate are the main advantages of this method. During the process, anodic dielectric breakdowns in form of short-living microdischarges are generated in a conductive liquid.
To analyse the effect of the electrolyte concentration on these microdischarges, the active anode surface is reduced to the tip of a wire with a diameter of 1 mm. The electrolyte consists of varying concentrations of potassium hydroxide (1 - 4 g/l) in distilled water.
Fast optical measurements with a high-speed camera are carried out for a better understanding of the development and evolution of single microdischarges and the accompanying gas evolution.
Optical emission spectroscopy allows the determination of electron densities with Stark broadening of Hα and scanning the treated wire tips with an electron microscope (SEM) enables to investigate the morphology of oxide layer. The measurements are performed in galvanostatic DC Mode with a current density of 1.27A/cm2.
To analyse the effect of the electrolyte concentration on these microdischarges, the active anode surface is reduced to the tip of a wire with a diameter of 1 mm. The electrolyte consists of varying concentrations of potassium hydroxide (1 - 4 g/l) in distilled water.
Fast optical measurements with a high-speed camera are carried out for a better understanding of the development and evolution of single microdischarges and the accompanying gas evolution.
Optical emission spectroscopy allows the determination of electron densities with Stark broadening of Hα and scanning the treated wire tips with an electron microscope (SEM) enables to investigate the morphology of oxide layer. The measurements are performed in galvanostatic DC Mode with a current density of 1.27A/cm2.
*The authors would like to thank the financial support by DFG via SFB 1316 (Project B5)
Presenters
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Jan-Luca Gembus
- Institute for Electrical Engineering and Plasma Technology, Ruhr University Bochum, Germany