Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Technical University of Denmark
- Cranfield University
- University of Antwerp
- University of Groningen
- Curtin University
- Danmarks Tekniske Universitet
- Elestor BV
- Heidelberg University
- ICN2
- KU LEUVEN
- Tallinn University of Technology
- University of Groningen; Groningen
- University of Luxembourg
- University of Tübingen
- Wageningen University & Research
- 5 more »
- « less
-
Field
-
investigate through a quantitative mechanistic model how mitochondrial morphology affects energetic states and can integrate mechanistically experimental findings of neurodegenerative disease research. Your
-
Department: Molecular -Morphology-Microscopy Regime Full-time Let’s shape the future - University of Antwerp The University of Antwerp is a dynamic, forward-thinking, European university. We offer
-
model, which maps online observable process parameters (e.g. spinneret voltage, flow rate etc.) to nanofiber product quality (e.g. morphology, diameter variance, all of which are only observable offline
-
appendages using the (halo)archaea as a model. Studying the infection mechanisms of archaeal viruses can provide insight into the evolutionary history of viruses and help to understand adaptation to extreme
-
Apply online now: https://karriere.klinikum.uni-heidelberg.de/index.php?ac=application&jobad_id=25541 PhD position - Functional and molecular characterization of AI-based morphological predictors
-
of the battery using e.g. in-house powder diffraction. Use in-house imaging experiments for detailed morphological analysis of the battery cells. Perform in situ and operando synchrotron X-ray diffraction and
-
-house powder diffraction. Use in-house imaging experiments for detailed morphological analysis of the battery cells. Perform in situ and operando synchrotron X-ray diffraction and imaging studies
-
: Multiscale modelling to better understand RFB behavior and identify optimal hierarchical shaped pore- and electrode-structure to encounter optimum electrolyte as well as electrical flow. Prototyping
-
appendages using the (halo)archaea as a model. Studying the infection mechanisms of archaeal viruses can provide insight into the evolutionary history of viruses and help to understand adaptation to extreme
-
-metallic clusters that combine plasmonic and catalytic metals These clusters will be deposited with high control over size and composition using cluster beam deposition on morphologically engineered TiO2