Issue 17, 2014

CNT–PVDF composite flow-through electrode for single-pass sequential reduction–oxidation

Abstract

In this study, a five-layer electrochemical CNT–PVDF filter that is thin, flexible, and stable is demonstrated to be effective and efficient for single-pass nitrobenzene mineralization by sequential reduction–oxidation. Key to the technology is development of a CNT–PVDF membrane that is mechanically stable, electrically conductive, and non-Faradaic, which is used to prevent CNT release from and electrochemical degradation of the Faradaic CNT electrodes. A five-layer electrochemical filter: (1) conductive & protective CNT–PVDF, (2) Faradaic CNT electrode, (3) insulating PVDF separator, (4) Faradaic CNT electrode, and (5) conductive & protective CNT–PVDF is formed by mechanical press. At a total cell potential of 4 V, the sequential electrochemical reduction–oxidation process is able to reduce >99% of the influent nitrobenzene to aniline then oxidize >80% of the aniline to non-aromatic products (mostly carbon dioxide) in a single-pass (∼5 s hydraulic residence time). The mineralization current efficiency is ∼20%, total cell potential is completely (>99%) distributed to the two electrodes, and the energy requirement is ∼36 000 kJ per mole of nitrobenzene degraded.

Graphical abstract: CNT–PVDF composite flow-through electrode for single-pass sequential reduction–oxidation

Supplementary files

Article information

Article type
Paper
Submitted
10 Oct 2013
Accepted
19 Dec 2013
First published
20 Dec 2013

J. Mater. Chem. A, 2014,2, 6185-6190

CNT–PVDF composite flow-through electrode for single-pass sequential reduction–oxidation

G. Gao, Q. Zhang and C. D. Vecitis, J. Mater. Chem. A, 2014, 2, 6185 DOI: 10.1039/C3TA14080F

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