List of publications:
Articles:
- Dörfler, M.A. & Kenkmann, T. 2020. Central uplift collapse in acoustically fluidized granular targets: Insights from analog modeling. Meteoritics & Planetary Science, 55: 441-456.
Conference Abstracts:
- Dörfler, M. A., Krietsch, H., Hergarten, S., Kenkmann, T., Rae, A. S. P., Müller, L. (2020). Roughness of Fracture Surfaces under Quasi-static and Dynamic Deformation Conditions. 18th TSK Symposium Cologne*, TSK abstracts 2020.
- Rae, A. S. P., Kenkmann, T., Padmanabha, V., Schäfer, F., Poelchau, M. H., Dörfler, M. A., Müller, L. 2020. Strength and Fragmentation of Rocks at High Strain Rates. 18th TSK Symposium Cologne*, TSK abstracts 2020.
- Padmanabha, V., Schäfer, F., Rae, A. S. P., Kenkmann, T., Dörfler, M. A., Müller, L. 2020: Characteristics of Tensile Failure in Rocks at High Strain Rate. 4th International Conference on Rock Dynamics and Applications**, RockDyn abstracts.
- Dörfler, M. A. & Kenkmann, T. 2018. Analogue Modeling of the Collapse of an Over-Heightened Central Peak: Clues to the Peak-Ring Formation at Chicxulub? 49th Lunar and Planetary Science Conference (2018), Abstract #1484
- Martellato, E., Wünnemann, K., Dörfler, M. A., Schuster, B. & Kenkmann, T. 2018. Experimental Investigation of the Formation of Complex Craters. European Planetary Science Congress 2018, EPSC Abstracts Vol. 12, EPSC2018-96, 2018
* The 2020 TSK conference was cancelled due to the Sars-Cov-2 pandemic, but the abstracts were accepted and sent out to all participants.
** The 2020 4th International Conference on Rock Dynamics and Applications was postponed to 2021 due to the Sars-Cov-2 pandemic.
For my master’s thesis I investigated the coseismic pulverization of carbonate rocks, focusing on dynamic, high strain rate deformation.
Through my work as a student assistant at the split Hopkinson pressure bar at the University of Freiburg I have also contributed to several research projects investigating dynamic fragmentation.
During my geological project (basically a second bachelor’s thesis) I used white light interferometry to investigate the roughness of quasi-statically and dynamically produced fracture surfaces. Several evaluation methods were developed and compiled into a MATLAB library + script.