Innovative Catalyst Platform Advances Understanding of Working Catalysts
© FHI
A novel catalyst platform, known as Laterally Condensed Catalysts (LCC), has been developed to enable design and analysis of the functional interface connecting the active mass to its support. This interface not only influences the chemical properties of the reactive interface but also controls its stability and hence the sustainability of the catalytic materials. The development was significantly supported by the use of operando spectroscopy at the BESSY II synchrotron, which made it possible to observe and understand the dynamic processes and structures under reaction conditions.
Unrestrained combinations in composition between active phase and support enable for example direct energy transfer to the reactive interface in electrocatalysis or electrical heating. The physical synthesis methodology within the FHI-HZB CatLab project, taken from solar cell technology, gives access to precise and homogeneous structures and chemistry. This facilitates the mechanistic understanding of working catalysts and their subsequent optimization through interrogating reactive and functional interfaces by operando spectroscopy. The thin film catalysts studied here were synthesized with the objective of designing the interface structure of performance catalysts and closing the material gap between model and real-world powder catalysts while minimizing the use of noble metals. Its unique flat and densely packed structure (LCC) enables to achieve a homogeneous high density of surface active sites, minimizing the content of material present in the “bulk” or subsurface of the active catalysts with benefical effects on the selelctivity of the catalyzed reaction.
This effort is detailed in a study published in Nature Communications, entitled "Rationally Designed Laterally-Condensed-Catalysts Deliver Robust Activity and Selectivity for Ethylene Production in Acetylene Hydrogenation." The study is part of the CatLab Project, a collaboration prominently involving the Fritz Haber Institute of the Max Planck Society (FHI), the Helmholtz-Zentrum Berlin für Materialien und Energie and the Max Planck Institute for Chemical Energy Conversion. The CatLab Project is funded by Federal Ministry of Education and Research (BMBF).
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- Protein crystallography at BESSY II: faster, better and more and more automaticMany diseases are linked to malfunctions of proteins in the organism. The three-dimensional architecture of these molecules is often highly complex, but it can provide valuable insights into biological processes and the development of drugs. X-ray diffraction at the MX beamlines of BESSY II can be used to decipher the 3D structure of proteins. To date, more than 5000 structures have been solved at the three MX beamlines. Here, we present a review and an outlook with Manfred Weiss, head of the research group for macromolecular crystallography.
- What Zinc concentration in teeth revealsTeeth are composites of mineral and protein, with a bulk of bony dentin that is highly porous. This structure is allows teeth to be both strong and sensitive. Besides calcium and phosphate, teeth contain trace elements such as zinc. Using complementary microscopy imaging techniques, a team from Charité Berlin, TU Berlin and HZB has quantified the distribution of natural zinc along and across teeth in 3 dimensions. The team found that, as porosity in dentine increases towards the pulp, zinc concentration increases 5~10 fold. These results help to understand the influence of widely-used zinc-containing biomaterials (e.g. filling) and could inspire improvements in dental medicine.