The group Structure and Mechanics of Advanced Materials Group (SMAM) performs research on structural and mechanical properties of diverse soft matter systems, including samples of biological origin, composite materials, as well as of metals and alloys. We are developing and applying various X-ray and neutron scattering techniques, diffraction and imaging methods. We operate in situ devices such as mechanical testing devices, a miniaturized laser powder bed fusion device for 3D printing of metals as well as microfluidic devices and in-situ 3D printing for ink-based soft materials, studying alignment in flow.
SMAM supports the user program at SLS and SINQ and welcomes active collaborations with Swiss or internationally based universities, research centres and industry with the aim to advance the use of large facilities for material science and engineering.
The group is closely linked to the Institut des Matériaux at the École Polytechnique Fédérale de Lausanne through Tenure-Track Assistant Professor Marianne Liebi. Teaching materials science at large scale facilities and supporting research at masters and doctoral level are the primary responsibilities of SMAM at EPFL. Part of Marianne Liebi's research group is located at the Chalmers University of Technology in Gothenburg, Sweden.
Marianne Liebi is an ERC starting grant holder of MUMOTT – Multi Modal Tensor Tomography. The project includes method development of tensor tomography, using X-rays as well as visible light and its application in materials and bio-science.
Steven Van Petegem is principle investigator in two Strategic Focus Area (SFA) consortiums: Multi-Mat – Multi-material laser powder-bed fusion and SMARTAM – Fast Optimization of Additively Manufactured Metallic Parts with a Combination of Adaptive Feedforward Control and Numerical Simulation.
The group arises from the PEM group in the Photon Science Divison.
Current Highlights and News
Mitigating Cracks in Multi-Material Printing
Integrating metallic powders with thin foils in laser powder bed fusion can reduce interfacial cracks and improve microstructure quality in titanium-aluminum multi-material printing.
Acoustic emission signature of a martensitic transformation
Acoustic emission monitoring in 3D printing: real-time insights into martensitic phase transformations and crack formation.
The Tipping Point!
Exciting to see that some of our research on Narwhal tusk made it into an educational videogame about climate change in the Arctic and its impact on some of its inhabitants!
Observing laser-induced recrystallization
Synchrotron X-ray diffraction sheds light on laser-induced local recrystallization .
Listening for Defects as They Happen
Experiments at the Swiss Light Source SLS help resolve a long-standing debate surrounding metal 3D laser printing.
Microstructural control of additively manufactured Ti-6Al-4V
In-situ Selective Laser Heat treatment is applied to induce martensite decomposition in Ti-6Al-4V