Sort by
Refine Your Search
-
Listed
-
Employer
-
Field
-
Your Job: To further develop the high-temperature electrolysis and fuel cell technology (Solid Oxide Cell, SOC), you will take over management of the merged departments "Electrochemistry" and
-
fuel cells have the highest efficiency of all available fuel cells. In order to eliminate existing restrictions of this technology, e.g. with regard to cycle stability and the still high production costs
-
applications, our expertise is concentrated on the innovative fields of hydrogen technologies and fuel cell production. As part of this thesis, you will investigate the limitations of current sheet metal forming
-
for lithium-ion battery cells and fuel cells. Within the scope of your thesis, you will investigate deep learning-based defect detection approaches. To this end, we use roll-to-roll processes for the efficient
-
Helmholtz-Zentrum Berlin für Materialien und Energie | Berlin, Berlin | Germany | about 2 months ago
research capabilities and activities. You develop your own research program on the study of surfaces and (buried) interfaces in energy conversion devices (e.g., solar cells, batteries, fuel cells, etc.). You
-
Your Job: In order to optimize the system efficiency of solid oxide electrolysers and fuel cells, the aim is to reduce the operating temperature below 600 °C. This requires the use of new solid
-
available to meet the energy requirements, including battery electric drives, fuel cells, biogas, or various synthetic fuels. The unique boundary conditions require tailor-made solutions. Thus, the objective
-
knowledge of the structural characterization of matter with e.g. powder diffraction Experience with energy materials, e.g. fuel cells, batteries, heterogeneous catalysts, interfaces A distinct advantage would
-
-chemical processes in batteries and fuel cells. Ourthermodynamic models describe reaction and transport of ions with partial differential equations. Our quantum chemical models describe the reactions
-
model and simulate physicochemical processes in batteries and fuel cells. Our thermodynamic models describe reaction and transport of ions with partial differential equations. Our quantum chemical models