M⁵

- Micro Mechanics and Multiscale Materials Modeling

Research

Prof. Dr.-Ing. habil. Bernhard Eidel

• Numerical Homogenization of micro-heterogeneous materials by two-scale finite element methods (FEHMM/FE²)
• Atomistic-continuum coupling for seamless nano-micro scale transitions by the Quasi-Continuum (QC) Method
• Atomistic-continuum coupling with scale separation based on homogenization
• Deep learning in Neural Networks
• Modeling of inelasticity: material models and time integration algorithms
• Error estimation and mesh adaptivity
• Biomechanics/Medical Engineering: Development of bionics-inspired, optimized hip-/knee endoprotheses
• Structural mechanics of (ultra)light cellular structures
• Coupled Problems: Phase field modeling of Li-ion batteries
• Topology opotimization
• Simulation analyses of damage-, localization and failure mechanisms and of stability problems

Dr.-Ing. Arun Prakash

• Atomistic modeling of deformation and failure in nanocrystalline materials
• Nanomechanics and small scale plasticity
• Atomistic studies of fundamental deformation processes in amorphous materials
• Experimentally informed atomistic and finite element simulations
• Multiscale modeling and simulation of forming processes
• Continuum and atomistic modeling of severe plastic deformation processes
• Crystal plasticity finite element and spectral modeling frameworks
• Unsupervised machine learning
• Data science and informatics with applications at the nanoscale
• Development of scale bridging models
• Software and method development