-
an applied research project focused on the development of AI/ML-based methods for the automation of laser processing techniques. In close collaboration with our industrial partner, you will design and
-
. The tasks will require a high degree of innovativeness, command of multi-scale asphalt and binder testing methods, as well as knowledge of the pavement design concepts. Experience in material modeling and
-
) methods applied to study hematopoiesis, such as drug administration via i.p, s.c. and i.v., blood sampling, bone marrow transplantation, tissue harvest and s.c. implantations, is highly recommended
-
evaporation, magnetron sputtering, spin-coating, photolithography, and plasma etching. Advanced optical and electronic methods will be used for device characterization. Job description The research activities
-
transfer. We use complementary approaches including cryo-EM, biophysical methods and in vivo functional assays to study the protein machineries involved in this process. Join our young, ambitious, and
-
sustainable energy and chemical process systems. Our research spans from the molecular level to the scale of systems. We develop methods to advance sustainable energy and chemical process systems from
-
free-electron laser (XFEL) facilities. The role will also involve sample preparation, and characterization using both standard lab-based methods (optical and scanning electron microscopy, magnetometry
-
of disease-related biomarkers, and study of organ-on-a-chip. We develop microfluid, optical and electrochemical methods in combination with microorganisms and cells to provide solutions for environmental and
-
data analysis. The successful candidate will also be involved in the preparation of samples and their characterization using standard laboratory-based methods (optical and scanning electron microscopy
-
2 PhD students work on developing lipid biomarkers for soil fertility. Propose your own research approaches to answer previously outlined research questions. Methods used in the group encompass a