Floating ‘artificial leaf’ for solar-to-hydrogen production

University of Cambridge scientists have developed lightweight floating photocatalyst devices that produce green hydrogen and syngas. The leaf-like photoelectrochemical devices show potential for scalability.

University of Cambridge researchers have designed ultra-thin, leaf-like devices that produce green hydrogen from water splitting.  The floating photoelectrochemical devices showed a 0.58% solar-to-hydrogen efficiency.

“With further development, we expect the floating leaves to match the performance of state-of-the-art artificial leaf prototypes, which is about 5-10% for solar to hydrogen production,” researcher Virgil Andrei told pv magazine.

The scientists assembled the 1.7 cm2 lightweight artificial leaves by attaching perovskite photocathodes to bismuth vanadate (BiVO4) photoanodes with a contact adhesive. They deposited the lead halide perovskite photocathodes onto indium tin oxide (ITO)-coated polyethylene terephthalate (PET) films. They then covered the resulting perovskite-BiVO4 photoelectrochemical devices with micrometer-thin, water-repellent carbon-based layers to prevent moisture degradation and water infiltration.

The artificial leaves can split water into hydrogen and oxygen or reduce CO2 to syngas.

“The current leaves can either develop hydrogen or syngas, depending on the catalyst choice,” said Andrei. “The devices are quite versatile, allowing us to easily integrate different catalysts for a range of products.”

The leaves produced visible carbon monoxide and hydrogen bubbles in a symmetric design during operation, which was key to maintaining balance while floating, the scientists said. Outside of the lab, lightweight reactors facilitated gas collection to aid floating during outdoor testing.

The devices show the potential to be scaled, noted the scientists. They said they produced larger-scale 100 cm2 samples with a comparable performance and stability to their 1.7 cm2 counterparts.

“We showed that the lightweight devices are compatible with modern, large-scale fabrication techniques. However, specialized equipment will be required to prepare these leaves on a square-meter scale,” Andrei said. “Acquiring such equipment and optimizing the deposition may take 5 years. Once these large-scale prototypes are manufactured and pass certain stability and performance standards, commercial products can become available within a few years.”

The scientists introduced the new hydrogen tech in “Floating perovskite-BiVO4 devices for scalable solar fuel production,” which was recently published in Nature.

The lab setting

Image: University of Cambridge/Virgil Andrei

This post appeared first on PV Magazine.

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