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Energy & Green Tech

A new Si-based photocatalyst allows for efficient solar-powered hydrogen synthesis.

A team of researchers, led by Professor Jungki Ryu in the School of Energy and Chemical Engineering at UNIST and Professor Soojin Park from Pohang University of Science and Technology (POSTECH), have achieved a significant breakthrough in the development of a hybrid silicon photocatalyst. This innovative catalyst utilizes solar power to produce hydrogen and high-value compounds efficiently, marking a major step forward in green hydrogen production technology.

The newly developed photocatalyst is both non-toxic and eco-friendly, addressing the limitations associated with previous catalysts that were not sunlight-responsive or posed toxicity concerns. Silicon-based photocatalysts demonstrate excellent light absorption properties, making them highly efficient in utilizing solar energy. Moreover, these non-toxic materials do not emit harmful chemicals during their production process.

Previous research faced challenges in achieving continuous production of hydrogen alongside high-value compounds due to a lack of suitable catalysts. Toxic catalysts used under strong base conditions often lead to environmental pollution issues. Additionally, as oxide layers formed on traditional silicon photocatalysts during reactions, it negatively impacted hydrogen production efficiency over time.

“Previous hydrogen production research has been limited to photocatalysts that absorb ultraviolet rays or toxic catalysts. Our non-toxic, low-cost silicon photocatalyst represents a significant improvement since it permits high-efficiency hydrogen synthesis via excellent sunlight absorption.”

Professor Jungki Ryu in the School of Energy and Chemical Engineering at UNIST.

To overcome these obstacles, the research team developed a hybrid silicon photocatalyst by uniformly coating nickel-doped graphene quantum dots onto the surface of 2–3 nm-thick silicon flakes. The modified surface enabled significantly higher hydrogen production efficiency compared to conventional silicon photocatalysts, achieving an impressive rate of 14.2 mmol gcat−1 h−1—a substantial improvement equating to approximately 28 times higher performance.

Furthermore, through oxidation reactions using biomass instead of water—an organic substance derived from biological sources—the hybrid silicon photocatalyst demonstrated its capability for producing high-value compounds alongside hydrogen production. The catalyst also maintained 98% of its original form, ensuring long-term stability.

Professor Ryu stated, “Previous research on hydrogen production has been limited to photocatalysts that absorb ultraviolet rays or involve toxic catalysts. Our non-toxic and cost-effective silicon photocatalyst is a significant advancement as it enables high-efficiency hydrogen production through superior solar absorption.”

Professor Park added, “The surface modification technique utilizing nickel-doped graphene quantum dots can be applied not only to silicon photocatalysts but also to various other types of photocatalysts, opening up new possibilities in energy applications.”

The research is published in the journal Advanced Materials.

More information: Yuri Choi et al, Solar Biomass Reforming and Hydrogen Production with Earth‐Abundant Si‐Based Photocatalysts, Advanced Materials (2023). DOI: 10.1002/adma.202301576

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