Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges
Electrochemical technology attracts much research interest for the treatment of metal complexes, but most electrocatalysts are incapable of effectively degrading metal complexes, which generally have highly stable cages with five or six rings coordinating with metal ions. To address this, a bridging...
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sg-ntu-dr.10356-1544212021-12-22T06:53:07Z Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges Pan, Meilan Liu, S. Chew, Jia Wei School of Chemical and Biomedical Engineering Singapore Membrane Technology Centre Engineering::Chemical engineering 1-Pyrenesulfonic Acid Electrochemical Activity Electrochemical technology attracts much research interest for the treatment of metal complexes, but most electrocatalysts are incapable of effectively degrading metal complexes, which generally have highly stable cages with five or six rings coordinating with metal ions. To address this, a bridging agent linking the catalysts and metal complexes can lower the energy barrier, and thus holds much promise to facilitate the removal of such pollutants. In this study, 1-pyrenesulfonic acid (PSA) functionalization of acidic nitrogen-doped graphene (ANG) is successfully synthesized and found to effectively remove metal complexes through electrochemical membrane filtration. Results indicate that PSA, interacting with Cu-EDTA via the strong ion exchange of super acidic sulfonic (−SO3H) groups, acts as a conductive “bridge” connecting the electrocatalyst and metal complexes to overcome the challenge with penetrating the “cage” structure of metal complexes. The pyrrolic nitrogen of ANG is found to be the active sites in the electrochemical process, with the intrinsic electrochemical activity realized by the bridging agent, namely, PSA. This study highlights the importance of compounds with sulfonyl groups in circumventing the stable “cage” of the metal complexes, and thereby paves the way for effective degradation of such pollutants. Ministry of Education (MOE) This work was supported by the Singapore GSK (GlaxoSmithKline) – EDB (Economic Development Board, Singapore) Trust Fund and Singapore Ministry of Education Tier 1 Grant (2019-T1-002-065). 2021-12-22T06:53:06Z 2021-12-22T06:53:06Z 2020 Journal Article Pan, M., Liu, S. & Chew, J. W. (2020). Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges. Advanced Functional Materials, 30(30), 2001237-. https://dx.doi.org/10.1002/adfm.202001237 1616-301X https://hdl.handle.net/10356/154421 10.1002/adfm.202001237 2-s2.0-85085681180 30 30 2001237 en 2019-T1-002-065 Advanced Functional Materials © 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. |
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Engineering::Chemical engineering 1-Pyrenesulfonic Acid Electrochemical Activity Pan, Meilan Liu, S. Chew, Jia Wei Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
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Electrochemical technology attracts much research interest for the treatment of metal complexes, but most electrocatalysts are incapable of effectively degrading metal complexes, which generally have highly stable cages with five or six rings coordinating with metal ions. To address this, a bridging agent linking the catalysts and metal complexes can lower the energy barrier, and thus holds much promise to facilitate the removal of such pollutants. In this study, 1-pyrenesulfonic acid (PSA) functionalization of acidic nitrogen-doped graphene (ANG) is successfully synthesized and found to effectively remove metal complexes through electrochemical membrane filtration. Results indicate that PSA, interacting with Cu-EDTA via the strong ion exchange of super acidic sulfonic (−SO3H) groups, acts as a conductive “bridge” connecting the electrocatalyst and metal complexes to overcome the challenge with penetrating the “cage” structure of metal complexes. The pyrrolic nitrogen of ANG is found to be the active sites in the electrochemical process, with the intrinsic electrochemical activity realized by the bridging agent, namely, PSA. This study highlights the importance of compounds with sulfonyl groups in circumventing the stable “cage” of the metal complexes, and thereby paves the way for effective degradation of such pollutants. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Pan, Meilan Liu, S. Chew, Jia Wei |
| format |
Article |
| author |
Pan, Meilan Liu, S. Chew, Jia Wei |
| author_sort |
Pan, Meilan |
| title |
Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
| title_short |
Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
| title_full |
Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
| title_fullStr |
Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
| title_full_unstemmed |
Realizing the intrinsic electrochemical activity of acidic N-doped graphene through 1-pyrenesulfonic acid bridges |
| title_sort |
realizing the intrinsic electrochemical activity of acidic n-doped graphene through 1-pyrenesulfonic acid bridges |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/154421 |
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1720447184477880320 |