AMOLF Researchers Create Ultra-Thin Solar Catalyst Complete

The catalyst, engineered at the nanoscale, enables highly selective photochemical reactions using only a fraction of the material normally required for such processes.

Close-up van een hand met pincet die een onderdeel manipuleert in een mechanisch apparaat met glanzende metalen componenten

Nanoscale Design, High Impact

Developed by the Hybrid Solar Cells Group in collaboration with the Photonic Materials Group, the catalyst leverages nanoscale light–matter interactions to enhance electron transfer and minimize energy loss. Because only a tiny amount of material is needed, the design is highly scalable and resource-efficient.

Promising Results for CO2 Conversion

Early experiments indicate that the catalyst can support selective CO2-to-hydrocarbon conversion under mild conditions. This makes it a strong candidate for future solar-powered chemical and fuel production systems.

“By engineering light–matter interactions at the nanoscale, we enable reactions that were previously inefficient or impossible,”

dr. elena rossi

Lead researcher

Next steps

The team will now focus on improving long-term stability and fine-tuning the catalyst for industrially relevant reactions.

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Hypersmart Matter

Material that can both store and process information for low-energy computing

Researchers at AMOLF and the University of Konstanz have developed a mechanical material that can store, move, and process information within the same physical structure. The findings, published in Physical Review Letters, could help inspire future computing technologies that use far less energy than conventional computers.

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Vrouw in witte labjas en veiligheidsbril in laboratorium met labapparatuur rondom haar, glimlachend.

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