Accelerating NADH oxidation and hydrogen production with mid-gap states of nitrogen-rich carbon nitride photocatalyst
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ABSTRACT: Summary Regeneration of electron carriers such as NAD+/NADH is highly desirable and essential for enzymatic conversions. Here, we demonstrate a sustainable strategy for the regeneration of NAD+ as an electron carrier via photon-assisted heterogeneous catalysis. For this, a mid-gap state induced nitrogen-rich polymeric carbon nitride (NPCN) catalyst was synthesized by an additive-assisted thermal copolymerization. Utilizing NPCN as a photocatalyst presented NADH photooxidation efficiency of over 98% and a high hydrogen production rate of 11.18 mmolg−1h−1 with an apparent quantum yield of 9.16% (λ = 420 nm), outperforming other state-of-art metal-free photocatalysts. The experimental and theoretical simulations suggest that mid-gap states in NPCN catalyst are main platform for charge-carrier separation that enhances the overall photocatalytic performance. Graphical abstract Highlights • Additive assisted synthesis of N-rich PCN (NPCN) with mid-gap states is proposed• About 98% of NADH oxidation is realized using NPCN photocatalyst• A photocatalytic hydrogen evolution rate of 11.18 mmolg−1h−1 was achieved on NPCN• Existence of mid-gap electronic states facilitate charge carrier separation Catalysis; Materials chemistry; Materials science.
SUBMITTER: Bhoyar T
PROVIDER: S-EPMC9713345 | biostudies-literature | 2022 Nov
REPOSITORIES: biostudies-literature
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