Jenko, D.; Palm, M.: Transmission electron microscopy of the Fe–Al–Ti–B alloys with additions of Mo. 19th International Microscopy Congress (IMC19), Sidney, Australia (2018)
Prokopčáková, P.; Švec, M.; Lotfian, S.; Palm, M.: Microstructure – property relationships of iron aluminides. 64. Metallkunde-Kolloquium Montanuniversität Leoben, Lech am Arlberg, Austria (2018)
Peng, J.; Moszner, F.; Vogel, D.; Palm, M.: Influence of the Al content on the aqueous corrosion resistance of binary Fe–Al alloys in H2SO4. Intermetallics 2017, Educational Center Kloster Banz, Bad Staffelstein, Germany (2017)
Peng, J.; Vogel, D.; Palm, M.: Influence of the Al content on the corrosion resistance of binary Fe–Al alloys in H2SO4. EUROMAT 2017 – European Congress and Exhibition on Advanced Materials and Processes, Thessaloniki, Greece (2017)
Palm, M.: Development and processing of advanced iron aluminide alloys for application at high temperatures. 62. Metallkunde Kolloquium
, Lech am Arlberg, Austria (2016)
Marx, V. M.; Palm, M.: The wet and hot corrosion behavior of iron aluminides. THERMEC 2016 – Int. Conf. on Processing & Manufacturing of Advanced Materials
, Graz, Austria (2016)
Palm, M.: Iron aluminides: From alloy development to processing. The Materials Chain from Discovery to Production (contributed talk), Bochum, Germany (2016)
Hasemann, G.; Gang, F.; Palm, M.; Bogomol, I.; Krüger , M.: Determining the ternary eutectic alloy composition on the Mo-rich side of the Mo–Si–B system. Advances in Materials & Processing Technologies – AMPT 2015, Madrid, Spain (2015)
International researcher team presents a novel microstructure design strategy for lean medium-manganese steels with optimized properties in the journal Science
This project aims to investigate the influence of grain boundaries on mechanical behavior at ultra-high strain rates and low temperatures. For this micropillar compressions on copper bi-crystals containing different grain boundaries will be performed.
Within this project we investigate chemical fluctuations at the nanometre scale in polycrystalline Cu(In,Ga)Se2 and CuInS2 thin-flims used as absorber material in solar cells.
This project aims to develop a testing methodology for the nano-scale samples inside an SEM using a high-speed nanomechanical low-load sensor (nano-Newton load resolution) and high-speed dark-field differential phase contrast imaging-based scanning transmission electron microscopy (STEM) sensor.
The thorough, mechanism-based, quantitative understanding of dislocation-grain boundary interactions is a central aim of the Nano- and Micromechanics group of the MPIE [1-8]. For this purpose, we isolate a single defined grain boundary in micron-sized sample. Subsequently, we measure and compare the uniaxial compression properties with respect to…