invent the materials of the future.
We are currently seeking skilled and motivated KIT students in mechanical/chemical engineering or materials science to complete their theses and/or join the team as a working student (HiWi). Please contact us with a brief CV and your current transcript of grades.
We currently do not have funded positions available but are always looking for motivated and hard working researchers. Funding for excellent candidates is available from the DFG (German Research Foundation), DAAD (German Academic Exchange Service) and the Alexander von Humboldt Foundation. We would be happy to assist you in applying.
We currently do not have funded positions available but are always looking for motivated and hard working researchers. Funding for excellent candidates is available from the DFG (German Research Foundation), DAAD (German Academic Exchange Service) and the Alexander von Humboldt Foundation. We would be happy to assist you in applying.
3D-PRINTING
PROCESSING
CHARACTERIZATION
TESTING
ANALYSIS
SIMULATION
What to expect?
Join a dynamic team with a flat hierarchy and conduct innovative and timely research at the intersection of mechanical engineering, materials science, and manufacturing technology. Providing a diverse scientific playing field for your ideas, we apply a multidisciplinary set of methodologies. Those are primarily experimental but are often complemented with computational simulations.
We construct metamaterial architectures, such as lattice trusses, minimal surface shells and composite designs, and synthesize micro- and nanometer scale structures and devices via high-resolution 3D-printing, like two-photon polymerization. In this, one of our key interests is the development heat treatment conversion routes to create nanoarchitected ceramics from specially engineered printable organic-inorganic polymer chemistries. Our characterization approach often includes scanning electron microscopy (SEM), in situ SEM mechanical testing and digital image correlation, nano-computed tomography, finite element simulation and optimization, as well as spectroscopy techniques, thermogravimetric analysis and differential scanning calorimetry.
As a member of the Cluster of Excellence 3D Matter Made to Order, our laboratory accesses a vast inventory of state-of-the art instrumentation and is part of a highly visible network of experts in the field of 3D additive manufacturing. Further, we are in close exchange with collaborative partners at leading institutions abroad, such as at the University of California, providing diverse opportunities for your individual professional development and to build an international network.