Schneider, P.; Sigel, R.; Lange, M. M.; Beier, F.; Renner, F. U.; Erbe, A.: Activation and fluoride-assisted phosphating of aluminium silicon coated steel. ACS Applied Materials and Interfaces 5 (10), pp. 4224 - 4232 (2013)
Kawano, T.; Renner, F. U.: Studies on Wetting Behaviour of Hot-dip Galvanizing Process by use of Model Specimens with Tailored Surface Oxides. Surf. Int. Anal. 44 (8), pp. 1009 - 1012 (2012)
Kawano, T.; Renner, F. U.: Tailoring Model Surface and Wetting Experiment for a Fundamental Understanding of Hot-dip Galvanizing. ISIJ International 51, 10, pp. 1703 - 1709 (2011)
Valtiner, M.; Ankah, G. N.; Bashir, A.; Renner, F. U.: Atomic force microscope imaging and force measurements at electrified and actively corroding interfaces: Challenges and novel cell design. Review of Scientific Instruments 82 (2), pp. 023703-1 - 023703-8 (2011)
Naraparaju, R.; Christ, H.-J.; Renner, F. U.; Kostka, A.: Effect of shot-peening on the oxidation behaviour of boiler steels. Oxidation of Metals 76 (3-4), pp. 233 - 245 (2011)
Borissov, D.; Pareek, A.; Renner, F. U.; Rohwerder, M.: Electrodeposition of Zn and Au–Zn alloys at low temperature in an ionic liquid. Physical Chemistry Chemical Physics 12 (9), pp. 2059 - 2062 (2010)
Gründer, Y.; Renner, F. U.; Lee,, T. L.: The electrodeposition of copper onto UHV-prepared GaAs(001) surfaces. Surface Science 603 (17), pp. L105 - L108 (2009)
Naraparaju, R.; Christ, H.-J.; Renner, F. U.; Kostka, A.: Dislocation Engineering and its effect on the oxidation behaviour. Materials at High Temperatures 29, pp. 116 - 122 (2012)
Duarte, M. J.; Brinckmann, S.; Renner, F. U.; Dehm, G.: Nanomechanical testing under environmental conditins of Fe-based metallic glasses. 22st International Symposium on Metastable Amorphous and Nanostructured Materials, ISMANAM 2015, Paris, France (2015)
Efficient harvesting of sunlight and (photo-)electrochemical conversion into solar fuels is an emerging energy technology with enormous promise. Such emerging technologies depend critically on materials systems, in which the integration of dissimilar components and the internal interfaces that arise between them determine the functionality.
Enabling a ‘hydrogen economy’ requires developing fuel cells satisfying economic constraints, reasonable operating costs and long-term stability. The fuel cell is an electrochemical device that converts chemical energy into electricity by recombining water from H2 and O2, allowing to generate environmentally-friendly power for e.g. cars or houses…