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    ERC Starting Grants for Asplund and Pastewka

    15.08.2017 13:52
    Dr. Maria Asplund and Prof. Dr. Lars Pastewka have been chosen to receive funding from one of the most significant European sources of support for junior researchers. The ERC distinguishes these researchers by presenting them with ERC Starting Grants of up to a total of almost 3 million euros for new projects. Maria Asplund and Lars Pastewka (from left to right). Photos: Klaus Polkowski, private source

    Maria Asplund and Lars Pastewka (from left to right). Photos: Klaus Polkowski, private source

    Maria Asplund of the Department of Microsystems Engineering (IMTEK) is receiving an ERC Starting Grant of almost 1.5 million euros for the project “SPEEDER”.
    Electrical fields can control how cells move at the edges of a wound, and thus influence how well skin injuries heal. However, until now there has not been a material that is suitable for use to stimulate the cells. Now, in the SPEEDER project, the electrical engineer Maria Asplund together with her research team from the BrainLinks-BrainTools Cluster of Excellence at IMTEK is developing a supercapacitive polymer. This material can store and release a particularly high amount of energy, enabling electrical fields to be maintained over an extended period of time. The researchers are planning to incorporate the material as active components in an electronic dressing: the 'SPEEDER'. In future this could be used in severe cases to speed up the healing process and prevent the wound becoming chronic. The method could also be of major significance to other fields of application, for example, in the production of artificial tissue, and in therapy with electrostimulation.

    Lars Pastewka of the Department of Microsystems Engineering (IMTEK) is receiving an ERC Starting Grant of almost 1.5. million euros for his project, “Emergence of Surface Roughness in Shaping, Finishing and Wear Processes (ShapingRoughness)”.
    Nearly all surfaces are rough. They look like mountain ranges when observed under a microscope. In technical applications, roughness determines, for example, whether a surface can be moistened with a liquid and whether it will adhere to another object. Detailed knowledge of why surfaces are rough is presently lacking, especially for surfaces created by mechanical processes, such as cutting, forming and finishing. Pastewka will use computer simulations to study microscopic processes during mechanical deformation to discover the mechanisms underlying formation of roughness and predict specific topographies of machined surfaces. The development of roughness likely takes place in a manner similar to that of mountain ranges, which form under extreme geological conditions such as the folding of tectonic plates. These processes appear to be scale-invariant: The structures that develop on mountain ranges at kilometer-scales and on atomic solid at nanometer-scales resemble each other. Pastewka’s research will enable control of functional properties such as wettability and adhesion in manufacturing processes. This opens the possibility to rationally design or even eliminate post-processing steps, such as surface finishing, thereby saving resources and cost.

    Contact:
    Dr. Maria Asplund
    Department of Microsystems Engineering
    University of Freiburg
    Tel.: 0761/203-67375
    E-Mail:

    Prof. Dr. Lars Pastewka
    Department of Microsystems Engineering
    University of Freiburg
    Tel.: 0761/203-67480
    E-Mail:



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