Helmholtz Research Field: Information

Institute of Material Systems Modeling

Portrait WMS

Photo: HZG

Members of the Institute of Material Systems Modeling work on the digitalisation of processes. Various coupled pysical phenomena are considered and appropriately described using numerical methods. As usual, different length- and timescales are considered. Computational methods like machine learning complement this endeavour, as they are capable of detecting previously unknown correlations, patterns, and trends from very large volumes of data.
The information provided by such methods are utilised for developing physically sound material models representing the basis of novel computer simulations. The numerical models implemented in the department 'Simulation of Solids and Structures' are increasingly used for predicting and optimising the mechanical behaviour of complex engineering structures as well as for optimising the manufacturing process of materials.


Advanced technologies of materials characterisation and concepts for component assessment are no longer thinkable without use of numerical methods. They facilitate an improved gaining of information from experiments, and they are indispensable in cases when:

  • experiments on real components are not possible or justified, for safety or other reasons, due to their size or complex load conditions;
  • parameter studies are to be carried out, such as variation of materials variables or load assumptions;
  • here are high requirements of operational safety concurrent with optimal exploitation of the material to its service limits;
Wms Bild Gkss Internet 1

Photo: HZG

Numerical simulations are however only as powerful and accurate, as the models on which they are based. Therefore, competence in the area of modelling of material and component behaviour under external influence is essential for advanced materials research and application. Here, the relationships between micro structure and global technical properties of engineering materials are of particular significance.

The finite element method (FEM) for tension and deformation analyses of complex structures is recognised as a flexible and well established instrument. However, commercially available programmes, e.g.. ABAQUS oder ANSYS , offer only what is respectively considered the state of art in material equations. Therefore, it is necessary in all materials research to continue the development and refinement of material models for the characterisation of deformation and damage.

Work Goals