Integrated manufacturing of REciclable multi-material COmposites for the TRANSport sector
Decoupling of Carrier Pathways in Au/Cu?Zn3In2S6 Through Bulk Hole Trapping and Surface Hot Electron Accumulation Enhances Photocatalytic Hydrogen Peroxide Production
We design and implement Au?Cu co?modified Zn3In2S6 catalyst with spatially decoupling charge carriers across bulk and surface sites, which effectively suppresses carrier recombination, drives surface hot electron accumulation and stabilizes intermediates for photocatalytic oxygen reduction. The optimized catalyst achieves an H2O2 evolution rate of 94.2 µmol g?1 min?1 using pure water without any sacrificial agents, far exceeding most reported photocatalysts. Artificial photosynthesis offers a sustainable route to H2O2 production but is hindered by charge recombination and non?selective reactive species generation, resulting in parasitic reactions that reduce selectivity and yield. Here, Au?Cu co?modified Zn3In2S6 (Au/Cu?d/ZIS) is presented, a catalyst that spatially decouples charge carriers across bulk and surface sites, suppressing recombination and stabilizing intermediates for photocatalytic oxygen reduction. Cu doping introduces trap states that localize holes in the bulk and improve the separation and transportation of bulk photogenerated carriers. Plasmonic Au nanoparticles drive surface hot electron accumulation and further contribute to the oxygen reduction reaction. The optimized catalyst achieves an H2O2 evolution rate of 94.2 µmol g?1 min?1 using pure water without any sacrificial agents, outperforming pristine Zn3In2S6 by nearly threefold. DRIFTS identifies stabilized oxygenated species on the catalyst surface, and DFT calculations demonstrate that Cu trap states lower energy barriers for •O2? formation, while Au NPs enhance the charge transfer and ORR reaction between ZIS and O2. The catalyst maintains stability and reusability, producing 2300 µmol g?1 of H2O2 under natural sunlight over 4 h with consistent performance across multiple cycles. Furthermore, it is successfully applied for bacterial sterilization and pharmaceutical pollutant degradation, demonstrating its potential for environmental remediation.
» Publication Date: 18/08/2025
This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement Nº 768737
