A1 A2 A3 A4 A5 A6 A7 A8 A9 B1 B2 B4 B5 B7 B8 B11 B12 B13 INF MGK PR

B5: 2D-plasma-liquid-solid interfaces – plasma electrolytic oxidation

Principal Investigators: A. Gibson, P. Awakowicz

Team


Awakowicz, Peter
(Principal Investigator)

Bracht, Vera
(PhD)

Gibson, Andrew
(Principal Investigator)

Description

ImageMicrodischarges formed in conductive liquids represent highly complex physical and chemical environments. The aim of this project is to develop a better understanding of these systems through an active combination of experimental measurements and numerical simulations. Building on the insights of the first period, a variety of optical and electrical diagnostics will be applied to microdischarges formed in contact with Al, Mg and W electrodes, in order to better understand the influence of the surface material on discharge formation. In addition to the direct insights derived from these measurements, they will be used to provide inputs to specially constructed 0D simulations of microdischarges formed in liquids, which will provide insights into the plasma-chemical kinetics taking place.

Publications

Thesis

  • Patrick Herrmanns
    Charakterisierung und Prozessoptimierung industriell relevanter Mikroplasmen: Von der Beschichtungstechnik bis zur Mikrosensorik (PhD thesis) - 10/2020
  • Simon Böddeker
    Elektrische Messtechnik und statistische Prozessdiagnostik an einem PEO-Beschichtungsprozess (MA) - 01/2020
  • Anna Lena Schöne
    Optische und elektrische Messtechnik an einem Einzelentladungsaufbau zur plasmaelektrolytischen Oxidation (BA) - 09/2019
  • Vera Bracht
    Plasma Electrolytic Oxidation (PhD thesis) - ongoing

Further reading

  • Phase resolved analysis of the homogeneity of a diffuse dielectric barrier discharge,
    S. Baldus, F. Kogelheide, N. Bibinov, K. Stapelmann, and P. Awakowicz,
    J. Phys. D: Appl. Phys. 48 375202 (2015)
  • Space-resolved characterization of high frequency atmospheric-pressure plasma in nitrogen, applying optical emission spectroscopy and numerical simul.
    Priyadarshini Rajasekaran, Cornelia Ruhrmann, Nikita Bibinov, Peter Awakowicz,
    J. Phys. D: Appl. Phys. 44 485205 (2011)

Powered by ChronoForms - ChronoEngine.com