Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Cranfield University
- Technical University of Denmark
- University of Antwerp
- University of Groningen
- Curtin University
- Elestor BV
- Heidelberg University
- ICN2
- KU LEUVEN
- Tallinn University of Technology
- UCL
- University of Groningen; Groningen
- University of Luxembourg
- University of Tübingen
- VIB
- Wageningen University & Research
- Wageningen University and Research Center
- 7 more »
- « less
-
Field
-
-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
-
targets the development of advanced coatings to prevent cell-to-cell propagation during runaway events. It combines experimental studies, numerical modelling, and real-world burner rig testing, culminating
-
less understood. A significant failure mode is electrochemical migration, which leads to short circuits and fire risk. The morphology and chemistry of dendrites are determined by the humidity and gas
-
when humidity and gas involved are more complex and less understood. A significant failure mode is electrochemical migration, which leads to short circuits and fire risk. The morphology and chemistry of
-
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
-
morphology (future and conditional) in Spanish, Italian and French. On the empirical side, the project will deliver a theoretically informed cross-linguistic description based on data collected via
-
Nanoparticles Group at ICN2, led by Dr. Neus G. Bastús, focuses on the design and synthesis of advanced inorganic nanomaterials through wet-chemistry routes, with precise control over size, morphology
-
-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
-
will feature use of surfaces with varying morphologies and wettabilities to understand the effect of change. The work will also have the possibility of undertaking complimentary CFD studies to aid in
-
. The intermediate working temperatures also allow PCFCs to integrate efficient catalysts with well-designed morphologies. To date, hydrogen remains the prevalent fuel for PCFCs, however, challenges persist owing