Summary
Renewable energy is key to tackling climate change and reducing our dependence on fossil fuels. The intermittent supply of renewable energy hampers its efficient usage and creates a pressing need for innovative energy conversion approaches. Energy-to-fuel conversion using plasma-assisted catalytic conversion (PLAC) is highly promising for producing urgently needed fuels from greenhouse gases. In PLAC, reactants are activated in a plasma discharge, allowing for remarkable efficiencies beyond the limits of thermal catalysis. The catalyst surface defines the reaction pathway and selectivity, and is thus key in catalyst design. However, at present the active state of catalyst surfaces in plasma is unknown, limiting the impact of PLAC by inhibiting the design of dedicated plasma catalysts.
In SURPLAS, I will overcome this challenge and unlock the full potential of PLAC by determining the surface reaction mechanisms of catalysts in plasma and demonstrating the rational design of plasma catalysts for CO2 hydrogenation. My expertise in surface reactions, materials design, and in situ spectroscopy forms the basis of a pioneering approach to analyzing surfaces while they are exposed to microwave plasma. My group’s unique embedding with plasma experts from industry and academia will facilitate the study of complex catalyst-plasma interactions. I will be the first to determine the active state of single-crystal surfaces and applied powder catalysts in plasma and to derive trends in selectivity and metal-support interactions in PLAC. This breakthrough in understanding will allow for the rational design of plasma catalysts, which I will validate by catalytic performance measurements.
This project will revolutionize PLAC by demonstrating catalyst design based on atomic-scale understanding of surface reactions in plasma. SURPLAS will allow me to lead the way into a new era of energy conversion, at a time when urgent need for fuels meets record growth in renewable energy.
In SURPLAS, I will overcome this challenge and unlock the full potential of PLAC by determining the surface reaction mechanisms of catalysts in plasma and demonstrating the rational design of plasma catalysts for CO2 hydrogenation. My expertise in surface reactions, materials design, and in situ spectroscopy forms the basis of a pioneering approach to analyzing surfaces while they are exposed to microwave plasma. My group’s unique embedding with plasma experts from industry and academia will facilitate the study of complex catalyst-plasma interactions. I will be the first to determine the active state of single-crystal surfaces and applied powder catalysts in plasma and to derive trends in selectivity and metal-support interactions in PLAC. This breakthrough in understanding will allow for the rational design of plasma catalysts, which I will validate by catalytic performance measurements.
This project will revolutionize PLAC by demonstrating catalyst design based on atomic-scale understanding of surface reactions in plasma. SURPLAS will allow me to lead the way into a new era of energy conversion, at a time when urgent need for fuels meets record growth in renewable energy.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101116278 |
| Start date: | 01-01-2024 |
| End date: | 31-12-2028 |
| Total budget - Public funding: | 1 500 000,00 Euro - 1 500 000,00 Euro |
Cordis data
Original description
Renewable energy is key to tackling climate change and reducing our dependence on fossil fuels. The intermittent supply of renewable energy hampers its efficient usage and creates a pressing need for innovative energy conversion approaches. Energy-to-fuel conversion using plasma-assisted catalytic conversion (PLAC) is highly promising for producing urgently needed fuels from greenhouse gases. In PLAC, reactants are activated in a plasma discharge, allowing for remarkable efficiencies beyond the limits of thermal catalysis. The catalyst surface defines the reaction pathway and selectivity, and is thus key in catalyst design. However, at present the active state of catalyst surfaces in plasma is unknown, limiting the impact of PLAC by inhibiting the design of dedicated plasma catalysts.In SURPLAS, I will overcome this challenge and unlock the full potential of PLAC by determining the surface reaction mechanisms of catalysts in plasma and demonstrating the rational design of plasma catalysts for CO2 hydrogenation. My expertise in surface reactions, materials design, and in situ spectroscopy forms the basis of a pioneering approach to analyzing surfaces while they are exposed to microwave plasma. My group’s unique embedding with plasma experts from industry and academia will facilitate the study of complex catalyst-plasma interactions. I will be the first to determine the active state of single-crystal surfaces and applied powder catalysts in plasma and to derive trends in selectivity and metal-support interactions in PLAC. This breakthrough in understanding will allow for the rational design of plasma catalysts, which I will validate by catalytic performance measurements.
This project will revolutionize PLAC by demonstrating catalyst design based on atomic-scale understanding of surface reactions in plasma. SURPLAS will allow me to lead the way into a new era of energy conversion, at a time when urgent need for fuels meets record growth in renewable energy.
Status
SIGNEDCall topic
ERC-2023-STGUpdate Date
12-03-2024
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