The resulting Co?rGO-P/PTA photocatalyst achieved high activity for hydrogen peroxide (H2O2) production in pure water under visible light, using a non-sacrificial approach. Hydrogen peroxide is a key industrial chemical, traditionally produced using the anthraquinone oxidation method, which is energy intensive and complex.
Artificial photosynthesis of H2O2 from water and oxygen, powered by solar energy and semiconductor photocatalysts, offers a sustainable alternative, though challenges remain with conventional photocatalysts due to limited catalytic sites and poor charge separation.
PTA nanosheets are effective for visible-light-driven H2O2 generation, but their potential is limited by charge separation inefficiencies and a shortage of catalytic sites. Graphene-based materials, especially reduced graphene oxide, are widely used to improve charge transfer and separation within photocatalytic systems.
Incorporating single-atom metals like cobalt enhances reactivity by maximizing the number of active centers and allows precise control of reaction pathways. Metal phthalocyanines are promising precursors for such catalysts due to their defined metal-nitrogen coordination, which prevents atom aggregation.
This work demonstrates the synthesis and integration of advanced materials to boost photocatalytic performance, presenting a step forward in more efficient and sustainable hydrogen peroxide production.
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Dalian Institute of Chemical Physics
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