Neugebauer, J.: Ab initio guided materials design: Application to doping and growth of group-III nitride. Colloquium, TH Ilmenau, Ilmenau, Germany (2013)
Neugebauer, J.: Modeling steels exhibiting unconventional deformation mechanisms based on ab initio based multiscale simulations. Kolloquium TH Ilmenau, Ilmenau, Germany (2013)
Neugebauer, J.: Modeling steels exhibiting unconventional deformation mechanisms based on ab initio based multiscale simulations. ESISM Workshop, Kyoto, Japan (2013)
Neugebauer, J.: Fully ab initio determination of free energies: Basis for inverse approaches in materials design. MRS Fall Meeting, Boston, MA, USA (2012)
Sandlöbes, S.; Friák, M.; Dick, A.; Zaefferer, S.; Pei, Z.; Zhu, L.-F.; Sha, G.; Ringer, S.; Neugebauer, J.; Raabe, D.: Combining ab initio calculations and high resolution experiments to improve the understanding of advanced Mg-Y and Mg-RE alloys. 7th Annual Conference of the ARC Centre of Excellence for Design in Light Metals, Melbourne, VIC, Australia (2012)
Körmann, F.; Dick, A.; Grabowski, B.; Hickel, T.; Neugebauer, J.: The influence of magnetic excitations on the phase stability of metals and steels. Seminar Talk at Institute for Pure and Applied Math, UCLA, University of California, Los Angeles, CA, USA (2012)
Neugebauer, J.: Ab initio based multiscale modeling of structural materials: From a predictive thermodynamic description to tailored mechanical properties. MMM 2012 - Multiscale Materials Modeling Conference, Singapore City, Singapore (2012)
Max Planck team explains dendrite propagation, paving the way for safer and longer-lasting next-generation batteries. They publish their findings in the journal Nature.
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 dynamic hardness of B2-iron aluminides at high strain rates using an in situ nanomechanical tester capable of indentation up to constant strain rates of up to 100000 s−1 and study the microstructure evolution across strain rate range.
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…