Newsportal - Ruhr-Universität Bochum
New energy conversion layer for biosolar cells
A research team from the Ruhr-Universität Bochum (RUB), together with colleagues from Lisbon, has produced a semi-artificial electrode that could convert light energy into other forms of energy in biosolar cells. The technique is based on the photosynthesis protein Photosystem I from cyanobacteria. The group showed that they could couple their system with an enzyme that used the converted light energy to produce hydrogen. The results were published online in advance in October 2020 in the journal Angewandte Chemie.
For the work, the RUB group consisting of Panpan Wang, Dr. Fangyuan Zhao, Dr. Julian Szczesny, Dr. Adrian Ruff, Dr. Felipe Conzuelo and Professor Wolfgang Schuhmann from the Center for Electrochemistry cooperated with the team consisting of Anna Frank, Professor Marc Nowaczyk and Professor Matthias Rögner from the Chair of Biochemistry of Plants as well as colleagues from the Universidade Nova de Lisboa.
Photosystem I is part of the photosynthesis machinery in cyanobacteria and plants. With the help of light energy, it can separate charges and thus generate high-energy electrons that can be transferred to other molecules, for example to protons for the production of hydrogen.
In earlier work, the Bochum scientists had already used the light-collecting protein complex photosystem I to design electrodes for biosolar cells. For this purpose, they covered an electrode with a photosystem I monolayer. In such monolayers, the photosystems are not stacked on top of each other, but lie side by side in the same plane. Photosystem I, however, usually occurs as a trimer, i.e. three photosystems are always linked together. Since the trimers cannot be packed close together, holes appear in the monolayer, which can lead to short circuits. This impairs the performance of the system. It was precisely this problem that the scientists solved in the present work.
Holes in the photosystem layer plugged
In the cyanobacterium Thermosynechococcus elongatus, photosystem I exists mainly as a trimer. Using a new extraction technique, the researchers were able to isolate additionally monomers from the organism, creating a photosystem I monolayer on the electrode in which the monomers filled the holes between the trimers. In this way, they reduced the short-circuit effects. The system achieved current densities twice as high as a system consisting only of trimers.
To show what the technique could be in principle used for, the scientists coupled it to a hydrogenase enzyme that produced hydrogen using electrons provided by the photosystem. “Future work will be directed toward even more efficient coupling between the photosystem monolayer and the integrated biocatalysts to realize practical biosystems for solar energy conversion,” the authors preview in their publication.
The work was financially supported by the German Research Foundation within the Cluster of Excellence Ruhr Explores Solvation, short Resolv (EXC2033 – project number 390677874), and within the Research Training Group 2341 “Microbial Substrate Conversion” as well as by the China Scholarship Council.
Panpan Wang et al: Closing the gap for electronic short-circuiting: Photosystem I mixed monolayers enable improved anisotropic electron flow in biophotovoltaic devices, in: Angewandte Chemie International Edition, 2020, DOI: 10.1002/anie.202008958
Prof. Dr. Wolfgang Schuhmann
Analytical Chemistry – Center for Electrochemistry
Faculty of Chemistry and Biochemistry
Phone: +49 234 32 26200
21 December 2020