HMN 2026: How to Charge gold nanorods with light energy

Gold nanorods are promising photocatalysts that can use light energy to drive chemical reactions—such as converting CO? into usable fuels or producing hydrogen from water. In this process, the nanorods act like tiny antennas that capture light and convert it into collective oscillations of their electrons. During the reaction, the particles can become electrically charged.

A research team at the University of Potsdam led by physicist Dr. Wouter Koopman has now, for the first time, directly observed how this charging process occurs and developed a model that describes the underlying mechanisms. The results pave the way for the targeted control of light-driven chemical reactions and catalytic systems. In the long term, these systems have a wide range of potential applications—from solar-powered chemical reactors to novel energy storage technologies.

The paper is published in the journal Nature Communications.

Photocharging is a central but previously elusive process in photocatalysis with nanoscale metal particles: under illumination, excess charge can accumulate, significantly influencing catalytic properties. In an in-situ study, the team was able to observe this effect directly and demonstrate that gold nanorods behave like “photochemical capacitors” under light exposure: they store electrons at their surface. Owing to the large surface-to-volume ratio, a substantial amount of charge can accumulate in an extremely small space, leading to pronounced changes in their optical and chemical properties.

“We were able to directly demonstrate that light alone is sufficient to generate electric potentials between a single nanoparticle and its environment,” explains Dr. Felix Stete, the study’s lead author. When light is absorbed, electron–hole pairs are created. The holes are transferred to surrounding molecules—such as ethanol—while the electrons remain on the particle.

“Our particles essentially behave like nanometer-sized electrolyzers, devices that split water into H₂ and O₂ with the help of electricity,” says Koopman, “except that they do not require an external electric voltage source.” In doing so, the researchers provide a new physical framework for better understanding and optimizing light-driven chemical reactions.

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