Regensburg 2013 – wissenschaftliches Programm

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MI: Fachverband Mikrosonden

MI 9: Poster: Microanalysis and Microscopy

MI 9.11: Poster

Mittwoch, 13. März 2013, 15:00–17:00, Poster B2

The Munich Scanning Positron Microscope — •Marcel Dickmann¹, Werner Egger¹, Christoph Hugenschmidt^2,3, Gottfried Koegel¹, Christian Piochacz^2,3, Peter Sperr¹, and Guenther Dollinger¹ — ¹Universität der Bundeswehr München, LRT2, Institut für Angewandte Physik und Messtechnik, D-85579 Neubiberg, Germany — ²Technische Universität München, Physik Department E21, D-85748 Garching, Germany — ³FRM II, Technische Universität München, D-85747 Garching, Germany

Positrons are very sensitive probes to analyse non-destructively small open volume defects, e.g. vacancies, vacancy clusters, and dislocations. From positron lifetime measurements defect-types and their concentrations can be determined. Conventional positron lifetime studies are of limited spatial resolution. Moreover, saturation trapping of positrons in defects may render a determination of concentrations impossible.
These disadvantages can be avoided using pulsed low-energy positron beams for lifetime measurements. By varying the beam energy, depth resolutions in the sub-µm-range can be obtained. These depth-profiles enable measurements of defect concentrations even at saturation trapping.
At our Institute a scanning positron microscope (SPM), which offers additional lateral resolution of ≥ 1 µm, has been developed. With this system defect distributions close to crack surfaces, created by monotonic fracture and in fatigue tests, have been successfully studied in pure Copper and in the alloy Al 6013. The main limitation in these studies was the low count-rate obtainable with conventional laboratory positron sources. Currently, the SPM is transferred to the intense positron source (NEPOMUC) at the FRM II research reactor in Munich in order to increase the beam intensity by four orders of magnitude. This will open unique new possibilities for the investigation of defect structures in solids . In particular, more systematic investigations with higher spatial resolution of fatigued and fractured samples will be possible.