Affiliation:
1. Department of Colloid Chemistry Max‐Planck‐Institute of Colloids and Interfaces Am Mühlenberg 1 14476 Potsdam Germany
2. Department of Chemistry Federal University of São Carlos São Carlos SP 13565–905 Brazil
3. HarwellXPS Research Complex at Harwell Rutherford Appleton Lab Didcot OX11 0FA UK
4. Department of Chemistry University College London 20 Gower Street London WC1H 0AJ UK
5. Department of Inorganic Chemistry Fritz‐Haber‐Institut der Max‐Planck‐Gesellschaft Faradayweg 4–6 14195 Berlin Germany
6. Department PVcomB Helmholtz‐Zentrum Berlin für Materialien und Energie Schwarzschildstraße 3 12489 Berlin Germany
7. Chemistry Division School of Science and Technology University of Camerino Via Madonna delle Carceri Italy
8. Department of Materials Science WW4‐LKO University of Erlangen‐Nuremberg Martensstraße 7 91058 Erlangen Germany
Abstract
AbstractMaterials dictate carbon neutral industrial chemical processes. Visible‐light photoelectrocatalysts from abundant resources will play a key role in exploiting solar irradiation. Anionic doping via pre‐organization of precursors and further co‐polymerization creates tuneable semiconductors. Triazole derivative‐purpald, an unexplored precursor with sulfur (S) container, combined in different initial ratios with melamine during one solid‐state polycondensation with two thermal steps yields hybrid S‐doped carbon nitrides (C3N4). The series of S‐doped/C3N4‐based materials show enhanced optical, electronic, structural, textural, and morphological properties and exhibit higher performance in organic benzylamine photooxidation, oxygen evolution, and similar energy storage (capacitor brief investigation). 50M‐50P exhibits the highest photooxidation conversion (84 ± 3%) of benzylamine to imine at 535 nm – green light for 48 h, due to a discrete shoulder (≈700) nm, high sulfur content, preservation of crystal size, new intraband energy states, structural defects by layer distortion, and 10–16 nm pores with arbitrary depth. This work innovates by studying the concomitant relationships between: 1) the precursor decomposition while C3N4 is formed, 2) the insertion of S impurities, 3) the S‐doped C3N4 property‐activity relationships, and 4) combinatorial surface, bulk, structural, optical, and electronic characterization analysis. This work contributes to the development of disordered long‐visible‐light photocatalysts for solar energy conversion and storage.
Funder
Max-Planck-Gesellschaft
Engineering and Physical Sciences Research Council
Cardiff University
University College London
Subject
General Physics and Astronomy,General Engineering,Biochemistry, Genetics and Molecular Biology (miscellaneous),General Materials Science,General Chemical Engineering,Medicine (miscellaneous)
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