Lebensohn, R.A.; Kanjarla, A.K.; Eisenlohr, P.: An elasto-viscoplastic formulation based on fast Fourier transforms for the prediction of micromechanical fields in polycrystalline materials. International Journal of Plasticity 32-33, pp. 59 - 69 (2012)
Yang, Y.; Wang, L.; Zambaldi, C.; Eisenlohr, P.; Barabash, R.; Liu, W.; Stoudt, M. R.; Crimp, M. A.; Bieler, T. R.: Characterization and Modeling of Heterogeneous Deformation in Commercial Purity Titanium. Journal of Microscopy 63 (9), pp. 66 - 73 (2011)
Blum, W.; Eisenlohr, P.: Structure Evolution and Deformation Resistance in Production and Application of Ultrafine-grained Materials -- the Concept of Steady-state Grains. Materials Science Forum 683, pp. 163 - 181 (2011)
Mekala, S.; Eisenlohr, P.; Blum, W.: Control of dynamic recovery and strength by subgrain boundaries - Insights from stress-change tests on CaF2 single crystals. Philosophical Magazine A 91 (6), pp. 908 - 931 (2011)
Yang, Y.; Wang, L.; Bieler, T.; Eisenlohr, P.; Crimp, M.: Quantitative Atomic Force Microscopy Characterization and Crystal Plasticity Finite Element Modeling of Heterogeneous Deformation in Commercial Purity Titanium. Metallurgical and Materials Transactions A 42 (3), pp. 636 - 644 (2011)
Amberger, D.; Eisenlohr, P.; Göken, M.: Influence of microstructure on creep strength of MRI 230D Mg alloy. Journal of Physics: Conference Series 240 (1), 012068, pp. 01268-1 - 01268-4 (2010)
Blum, W.; Eisenlohr, P.: A simple dislocation model of the influence of high-angle boundaries on the deformation behavior of ultrafine-grained materials. Journal of Physics: Conference Series 240 (1), 012136, pp. 012136-1 - 012136-4 (2010)
Liu, B.; Raabe, D.; Roters, F.; Eisenlohr, P.; Lebensohn, R. A.: Comparison of finite element and fast Fourier transform crystal plasticity solvers for texture prediction. Modelling and Simulation in Materials Science and Engineering 18 (8), 085005, pp. 085005-1 - 085005-21 (2010)
Tjahjanto, D. D.; Eisenlohr, P.; Roters, F.: A novel grain cluster-based homogenization scheme. Modelling and Simulation in Materials Science and Engineering 18 (1), 015006, pp. 015006-1 - 015006-21 (2010)
Wang, L.; Eisenlohr, P.; Yang, Y.; Bieler, T. R.; Crimp, M. A.: Nucleation of paired twins at grain boundaries in titanium. Scripta Materialia 63, pp. 827 - 830 (2010)
Wang, L.; Yang, Y.; Eisenlohr, P.; Bieler, T. R.; Crimp, M. A.; Mason, D. E.: Twin Nucleation by Slip Transfer across Grain Boundaries in Commercial Purity Titanium. Metallurgical and Materials Transactions A 41 (2), pp. 421 - 430 (2010)
Sadrabadi, P.; Eisenlohr, P.; Wehrhan, G.; Stäblein, J.; Parthier, L.; Blum, W.: Evolution of dislocation structure and deformation resistance in creep exemplified on single crystals of CaF2. Materials Science and Engineering A 510-511, pp. 46 - 50 (2009)
Amberger, D.; Eisenlohr, P.; Göken, M.: Microstructural evolution during creep of Ca-containing AZ91. Materials Science and Engineering A 510-511, pp. 398 - 402 (2009)
Bieler, T. R.; Crimp, M. A.; Yang, Y.; Wang, L.; Eisenlohr, P.; Mason, D. E.; Liu, W.; Ice, G. E.: Strain Heterogeneity and Damage Nucleation at Grain Boundaries during Monotonic Deformation in Commercial Purity Titanium. Journal of Microscopy 61 (12), pp. 45 - 52 (2009)
Scientists of the Max-Planck-Institut für Eisenforschung pioneer new machine learning model for corrosion-resistant alloy design. Their results are now published in the journal Science Advances
Developing and providing accurate simulation techniques to explore and predict structural properties and chemical reactions at electrified surfaces and interfaces is critical to surmount materials-related challenges in the context of sustainability, energy conversion and storage. The groups of C. Freysoldt, M. Todorova and S. Wippermann develop…
About 90% of all mechanical service failures are caused by fatigue. Avoiding fatigue failure requires addressing the wide knowledge gap regarding the micromechanical processes governing damage under cyclic loading, which may be fundamentally different from that under static loading. This is particularly true for deformation-induced martensitic…
The structure of grain boundaries (GBs) is dependent on the crystallographic structure of the material, orientation of the neighbouring grains, composition of material and temperature. The abovementioned conditions set a specific structure of the GB which dictates several properties of the materials, e.g. mechanical behaviour, diffusion, and…
Smaller is stronger” is well known in micromechanics, but the properties far from the quasi-static regime and the nominal temperatures remain unexplored. This research will bridge this gap on how materials behave under the extreme conditions of strain rate and temperature, to enhance fundamental understanding of their deformation mechanisms. The…