ERC Synergy Grant

Directed evolution of catalysts for the energy transition

Alfred Ludwig, professor for Materials Discovery and Interfaces, is involved in the Synergy Grant from Ruhr University Bochum. copyright: RUB, Marquard

Catalysts should be efficient and durable. To find them, four teams are systematically working together on new concepts. They are being funded by the European Research Council (ERC) with 10 million euros.

Hydrogen is considered the energy carrier of the future. To produce it, reactions have to be catalysed, some of which take place under extreme conditions. Previous electrocatalysts usually cannot withstand this for long – new materials are needed that are both powerful and durable, and ideally do not contain expensive and scarce elements. A Danish-German-Swiss research consortium is systematically taking a new approach in the project “Directed Evolution of Metastable Electrocatalyst Interfaces for Energy Conversion“, or DEMI for short. DEMI will be funded for the next six years with around 10 million euros as a Synergy Grant from the European Research Council ERC, the highest award for researchers in the EU.

The needle in the haystack

Materials consisting of five or more elements are particularly promising as electrocatalysts. The researchers are practically looking for a needle in a haystack, because there is an almost infinite number of possible compounds. In order to be able to perform a targeted search, the scientists Professor Jan Rossmeisl from the University of Copenhagen (Denmark), Professor Alfred Ludwig from the Ruhr University Bochum (Germany), Professor Karl Mayrhofer from the Helmholtz Institute Erlangen-Nuremberg/Friedrich Alexander University Erlangen-Nuremberg (Germany) and Professor Matthias Arenz from the University of Bern (Switzerland) are pooling their expertise.

The Copenhagen researchers calculate promising material combinations based on theoretical electrochemistry and simulations. They follow an evolutionary principle by making small changes to promising combinations and checking whether they have a positive or negative effect. In this way, they identify and follow the path to ever better materials. Among other things, the Bochum team is carrying out evolutionary screening with novel microscale materials libraries. Thousands of materials that are produced at the same time are then exposed to extreme electrochemical conditions in order to identify the survivable ones very quickly. On this basis, further materials libraries are produced, which the Erlangen researchers examine in high throughput for their electrochemical performance. The Bern team will then use the best material combinations to produce catalysts in the form of nanoparticles that could be transferred to applications.

Performance in the long term

DEMI will make important contributions to significantly increase the efficiency of electrolysis and fuel cells with new catalyst materials, thus reducing the costs of the technologies.

“We understand activity of catalysts much better than we understand stability. We can have different hypotheses of what determines stability, but it takes the combination of different approaches we have in DEMI to develop a theory for metastability,“ says Jan Rossmeisl. The researchers’ goal is to find materials that can perform for a long time under load. “Previously described materials were sometimes very efficient, but quickly lost their capabilities in application, so they never made it into practice,“ explains Alfred Ludwig, who is also advancing the design of new materials for sustainable energy systems as Director of the Center for Interfacially Dominated High Performance Materials (Zentrum für Grenzflächendominierte Höchstleistungswerkstoffe, ZGH) and the Research Center Future Energy Materials and Systems. “Our goal is therefore to find a metastable system that delivers good catalytic performance over a long time.“

“With our data-driven, interconnected approach, we are striving in DEMI for a breakthrough in understanding metastability of interfaces,“ explains Karl Mayrhofer. “This will result in catalysts with high integral performance over the entire lifetime.“ “The stability of catalysts is rarely the focus of research. This is changing with our project,“ explains Matthias Arenz. “We expect to find both fundamental insights and novel catalysts for the energy transition.“

Three reactions are particularly important for applications: For fuel cells, the oxygen reduction reaction, which is already well understood, and the oxygen evolution reaction - OER for short. The latter is considered a key reaction, because it takes place under such difficult conditions that almost all previous catalysts dissolve within a short time. The third important reaction is the CO2 reduction reaction. This is less about the durability of the catalysts and more about their selectivity, since one wants to convert CO2 into other substances that can be used sensibly, as efficiently and exclusively as possible.