R. Schäublin scite author profile

The growing need to store increasing amounts of renewable energy has recently triggered substantial R&D efforts towards efficient and stable water electrolysis technologies. The oxygen evolution reaction (OER) occurring at the electrolyser anode is central to the development of a clean, reliable and emission-free hydrogen economy. The development of robust and highly active anode materials for OER is therefore a great challenge and has been the main focus of research. Among potential candidates, perovskites have emerged as promising OER electrocatalysts. In this study, by combining a scalable cutting-edge synthesis method with time-resolved X-ray absorption spectroscopy measurements, we were able to capture the dynamic local electronic and geometric structure during realistic operando conditions for highly active OER perovskite nanocatalysts. BaSrCoFeO as nano-powder displays unique features that allow a dynamic self-reconstruction of the material's surface during OER, that is, the growth of a self-assembled metal oxy(hydroxide) active layer. Therefore, besides showing outstanding performance at both the laboratory and industrial scale, we provide a fundamental understanding of the operando OER mechanism for highly active perovskite catalysts. This understanding significantly differs from design principles based on ex situ characterization techniques.

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Present development status of EUROFER and ODS-EUROFER for application in blanket concepts

Lindau

Möslang

Rieth

et al. 2005

Fusion Engineering and Design

445

168

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The microstructure and associated tensile properties of irradiated fcc and bcc metals

Victoria¹,

Baluc²,

Bailat³

et al. 2000

Journal of Nuclear Materials

318

155

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Optimization of the structural characteristics of CaO and its effective stabilization yield high-capacity CO2 sorbents

et al. 2018

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Calcium looping, a CO2 capture technique, may offer a mid-term if not near-term solution to mitigate climate change, triggered by the yet increasing anthropogenic CO2 emissions. A key requirement for the economic operation of calcium looping is the availability of highly effective CaO-based CO2 sorbents. Here we report a facile synthesis route that yields hollow, MgO-stabilized, CaO microspheres featuring highly porous multishelled morphologies. As a thermal stabilizer, MgO minimized the sintering-induced decay of the sorbents’ CO2 capacity and ensured a stable CO2 uptake over multiple operation cycles. Detailed electron microscopy-based analyses confirm a compositional homogeneity which is identified, together with the characteristics of its porous structure, as an essential feature to yield a high-performance sorbent. After 30 cycles of repeated CO2 capture and sorbent regeneration, the best performing material requires as little as 11 wt.% MgO for structural stabilization and exceeds the CO2 uptake of the limestone-derived reference material by ~500%.

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R. Schäublin

Dynamic surface self-reconstruction is the key of highly active perovskite nano-electrocatalysts for water splitting

Present development status of EUROFER and ODS-EUROFER for application in blanket concepts

The microstructure and associated tensile properties of irradiated fcc and bcc metals

Optimization of the structural characteristics of CaO and its effective stabilization yield high-capacity CO2 sorbents

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