Success rate 100 percent: HZB teams get third party funding for Solar Fuel projects

At the HZB Institute for Solar Fuels, also nanostructures in metal oxides are explored as efficient catalyst materials for artificial photosynthesis.

At the HZB Institute for Solar Fuels, also nanostructures in metal oxides are explored as efficient catalyst materials for artificial photosynthesis. © HZB

Converting solar energy and storing it in form of solar fuels, is one of the great scientific and technological challenges today to enable the transition into a more sustainable future powered by renewable energies. Scientists at the HZB institute for Solar Fuels are exploring new semiconductor materials in order to develop compact, robust and economic solutions for “artificial photosynthesis”. They have submitted four research projects in collaboration with partners from universities for funding by the German Research Association (Deutsche Forschungsgemeinschaft DFG) in the Priority Programme „Fuels Produced Regeneratively Through Light-Driven Water Splitting” (SPP 1613). All four projects have now been approved for funding.

“A success rate of 100 percent in this highly competitive call is truly remarkable, since only half of the submitted proposals could be funded”, Professor Roel van de Krol, head of the HZB Institute for Solar Fuels states. “This means we can further strengthen and expand our institute’s activities”. The first three projects are extensions of already running projects, while the 4th one is a new activity.

The objective is to investigate artificial photosynthesis based on solid-state inorganic materials from a fundamental scientific perspective as well as the aspects of material science required for its technological implementation. The goal is to convert solar energy into storable fuels, in this case hydrogen, which has a high gravimetric energy density and can be safely stored and used whenever needed, either in a fuel cell to generate electricity or as a base component for the production of synthetic hydrocarbon fuels.


The approved projects are:

  • Development of catalysts, namely manganese oxides and molybdenum sulphides, for an implementation in a light-driven water-splitting device using a multi-junction solar cell. Partner: Prof. H. Dau (PI, FU-Berlin), Prof. P. Kurz (University Freiburg i. Br.), Prof. S. Fiechter (HZB).
  • High-throughput characterization of multinary transition metal oxide and oxynitride libraries. New materials for solar water splitting with improved properties. Partner: Prof. Wolfgang Schuhmann (PI, Ruhr University Bochum), Prof. Alfred Ludwig (Ruhr University Bochum), Prof. S. Fiechter (HZB).
  • Novel thin film composites and co-catalysts for visible light-induced water splitting. Partner: M. Behrens (Uni Duisburg), A. Fischer (Uni Freiburg), M. Lerch (TU Berlin), T. Schedel-Niedrig (HZB).
  • Development of optimum bandgap photoanodes for tandem water-splitting cells based on doped complex metal oxides and III-V semiconductors coupled to water oxidation electrocatalysts. Partner: R. Beranek (PI, Ruhr University Bochum), A. Devi (Ruhr University Bochum), R. Eichberger (HZB).

arö


You might also be interested in

  • The future of BESSY
    News
    07.03.2024
    The future of BESSY
    At the end of February 2024, a team at HZB published an article in Synchrotron Radiation News (SRN). They describe the next development goals for the light source as well as the BESSY II+ upgrade programme and the successor source BESSY III.

  • 14 parameters in one go: New instrument for optoelectronics
    Science Highlight
    21.02.2024
    14 parameters in one go: New instrument for optoelectronics
    An HZB physicist has developed a new method for the comprehensive characterisation of semiconductors in a single measurement. The "Constant Light-Induced Magneto-Transport (CLIMAT)" is based on the Hall effect and allows to record 14 different parameters of transport properties of negative and positive charge carriers. The method was tested now on twelve different semiconductor materials and will save valuable time in assessing new materials for optoelectronic applications such as solar cells.
  • Sodium-ion batteries: How doping works
    Science Highlight
    20.02.2024
    Sodium-ion batteries: How doping works
    Sodium-ion batteries still have a number of weaknesses that could be remedied by optimising the battery materials. One possibility is to dope the cathode material with foreign elements. A team from HZB and Humboldt-Universität zu Berlin has now investigated the effects of doping with Scandium and Magnesium. The scientists collected data at the X-ray sources BESSY II, PETRA III, and SOLARIS to get a complete picture and uncovered two competing mechanisms that determine the stability of the cathodes.