Park, Hyunho Park, Soo Young 2025-03-23T11:30:17Z 2025-03-23T11:30:17Z 2025-03-19 2025-04 2398-4902 https://pubs.kist.re.kr/handle/201004/152073 Developing efficient and stable metal-free photocatalysts for hydrogen evolution reaction (HER) in seawater is crucial for advancing sustainable hydrogen production. While the potential of graphene quantum dots (GQDs) as HER photocatalysts has been established, they face limitations such as inadequate spectral absorption in the visible light spectrum and the presence of electron trap sites. This study introduces a metal-free photocatalyst composed of hexylamine-functionalized graphene quantum dots (GQD-HA) in combination with the ionic organic dye TPATCS, specifically engineered to tackle the challenges associated with HER in seawater. The introduction of amphiphilic assembly between GQD-HA and TPATCS results in strong intermolecular interactions, forming a robust and stable nanostructure. This structure not only demonstrates superior hydrogen evolution rates in simulated seawater compared to standalone TPATCS but also maintains a stable zeta potential and consistent morphology under irradiation, highlighting its significant photostability. The amphiphilic assembly enhances the photocatalyst's performance by effectively passivating electron trapping sites through the formation of amide bonds between GQD and HA, which improves charge separation and transfer while restoring n-type conductivity. These features are critical for optimized HER activity. This approach showcases a promising strategy for developing efficient, stable, metal-free photocatalysts for seawater HER, offering new perspectives on the design of self-assembled dye-sensitized photocatalysts for sustainable energy solutions. English ROYAL SOC CHEMISTRY Amphiphilic self-assembled dye-sensitized graphene quantum dots for efficient hydrogen evolution in seawater Article 10.1039/d5se00148j 1 Sustainable Energy & Fuels, v.9, no.8, pp.2175 - 2183 Sustainable Energy & Fuels 9 8 2175 2183 N scie scopus 001442094300001 Chemistry, Physical Energy & Fuels Materials Science, Multidisciplinary Chemistry Energy & Fuels Materials Science Article WATER PHOTOCATALYST OXIDE