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A recent collaborative report, published in Science, including RASEI Fellow Niels Damrauer, addresses a key issue for light-driven chemistry, potentially opening up possibilities for future energy-efficient chemical manufacturing.

Chemical reactions typically require an input of energy to proceed, this can be through heating, or introduction of chemical energy in the form of reactive chemicals. Recently, light-driven chemistry has emerged as a more energy efficient alternative. The principle is to use energy from light, which is absorbed by a catalyst. Excited by the light energy the catalyst can then donate an electron to the chemicals undergoing the desired chemical transformation.

This sounds great – light-driven reactions? One of the key issues in this class of chemistry is back transfer of the electron. This means that after the catalyst donates the electron to the reagents, instead of doing the desired reaction, the reagent gives the electron back to the catalyst. This can significantly slow down the desired reaction, even sometimes shutting it down.

This report details a new type of catalyst that can overcome this back transfer of electrons. Through rationale design of the catalyst the new system uses a chemical reaction as a catch, preventing the back transfer from the reagent and strongly favoring the desired reaction.

To highlight the impact of this work, which was completed as part of the NSF Center for Chemical Innovation Center for Sustainable Photoredox Catalysis (SuPRCat), ÌÒÉ«ÊÓƵ student Arindam Sau, a member of the Damrauer group, teamed up with a graduate student and postdoc from Colorado State University to put together a review and summary of this work that was recently published in The Conversation. Check out the highlight to get a full picture of the impact of this work.ÌýÌý