%0 Journal Article %J Plasma Sources Science and Technology %D 2014 %T Asymmetric particle fluxes from drifting ionization zones in sputtering magnetrons %A Matjaž Panjan %A Robert Franz %A André Anders %K Instrumentation and measurement %K Plasma physics %K Surfaces, interfaces and thin films %X

Electron and ion fluxes from direct current and high-power impulse magnetron sputtering (dcMS and HiPIMS) plasmas were measured in the plane of the target surface. Biased collector probes and a particle energy and mass analyzer showed asymmetric emission of electrons and of singly and doubly charged ions. For both HiPIMS and dcMS discharges, higher fluxes of all types of particles were observed in the direction of the electrons' E x B drift. These results are put in the context with ionization zones that drift over the magnetron's racetrack. The measured currents of time-resolving collector probes suggest that a large fraction of the ion flux originates from drifting ionization zones, while energy-resolving mass spectrometry indicates that a large fraction of the ion energy is due to acceleration by an electric field. This supports the recently proposed hypothesis that each ionization zone is associated with a negative–positive–negative space charge structure, thereby producing an electric field that accelerates ions from the location where they were formed.

%B Plasma Sources Science and Technology %V 23 %P 025007 %8 04/2014 %N 2 %! Plasma Sources Sci. Technol. %R 10.1088/0963-0252/23/2/025007 %0 Journal Article %J Applied Physics Letters %D 2013 %T Drifting potential humps in ionization zones: The “propeller blades” of high power impulse magnetron sputtering %A André Anders %A Matjaž Panjan %A Robert Franz %A Joakim Andersson %A Pavel A. Ni %K Electric fields %K ionization %K plasma ionization %K sputter deposition %K sputtering %X

Ion energy distribution functions measured for high power impulse magnetron sputtering show features, such as a broad peak at several 10 eV with an extended tail, as well as asymmetry with respect to E × B, where E and B are the local electric and magnetic field vectors, respectively. Here it is proposed that those features are due to the formation of a potential hump of several 10 V in each of the traveling ionization zones. Potential hump formation is associated with a negative-positive-negative space charge that naturally forms in ionization zones driven by energetic drifting electrons.

%B Applied Physics Letters %V 103 %P 144103 %8 10/2013 %N 14 %! Appl. Phys. Lett. %R 10.1063/1.4823827