ALBA Synchrotron

Researchers from the IMDEA Energy Institute in Madrid have used the CIRCE-NAPP beamline of ALBA to study the artificial photosynthesis process, that is, the chemical reaction that plants and other photosynthetic organisms use to transform the Sun's energy into chemical energy.
The goal of their research is to selectively control the products of the chemical reaction to obtain those that have industrial and energetic interest. At the CIRCE-NAPP station, scientists have analyzed the different reaction products based on the catalysts used.
The direct conversion of solar energy into chemical energy (that is, fuels) using widely abundant and recyclable raw materials (carbon dioxide, water, oxygen and nitrogen) is destined to become one of the pillars that sustain the transition of the current linear economy to a circular economy. One of the technologies in this frame is artificial photosynthesis, which employs catalysts capable of using light as energy source to convert carbon dioxide and water into useful products for chemistry and energy. Since there are different possible products of this conversion, each with a different utility, controlling the selectivity of the process towards one or another is key to the implementation of this technology.
In collaboration with the ALBA Synchrotron and the National University of San Martín in Argentina, researchers from the Photoactivated Processes Unit of IMDEA Energy have published a study on the control of the final products of artificial photosynthesis using as catalysts perovskite-type oxides with silver nanoparticles on their surface. Using several physico-chemical techniques, this work sheds light onto the molecular mechanisms that drive the selectivity changes observed when using different versions of these catalysts. The obtained products range from carbon monoxide, which in combination with hydrogen can be used for subsequent chemical syntheses, to methanol, directly usable, for example, in fuel cells.
Chemical products produced in the chemical reaction depending on the catalyst used.
With the collaboration of Fundación Española para la Ciencia y la Tecnología. The ALBA Synchrotron is part of the UCCs of the FECYT and has received support through the FCT-20-15798 project.