Issue 20, 2012

Microfluidic photoelectrocatalytic reactors for water purification with an integrated visible-light source

Abstract

This paper reports experimental studies using the photoelectrocatalytic effect to eliminate a fundamental limit of photocatalysis – the recombination of photo-excited electrons and holes. The fabricated reactor has a planar reaction chamber (10 × 10 × 0.1 mm3), formed by a blank indium tin oxide glass slide, an epoxy spacer and a BiVO4-coated indium tin oxide glass substrate. A blue light-emitting diode panel (emission area 10 × 10 mm2) is mounted on the cover for uniform illumination of the reaction chamber. In the experiment, positive and negative bias potentials were applied across the reaction chamber to suppress the electron/hole recombination and to select either the hole-driven or electron-driven oxidation pathway. The negative bias always exhibits higher performance. It is observed that under −1.8 V the degradation rate is independent of the residence time, showing that the accompanying electrolysis can solve the oxygen deficiency problem. The synergistic effect of photocatalysis and electrocatalysis is observed to reach its maximum under the bias potential of ± 1.5 V. The photoelectrocatalytic microreactor shows high stability and may be scaled up for high-performance water purification.

Graphical abstract: Microfluidic photoelectrocatalytic reactors for water purification with an integrated visible-light source

Article information

Article type
Paper
Submitted
28 Apr 2012
Accepted
24 Jul 2012
First published
27 Jul 2012

Lab Chip, 2012,12, 3983-3990

Microfluidic photoelectrocatalytic reactors for water purification with an integrated visible-light source

N. Wang, X. Zhang, B. Chen, W. Song, N. Y. Chan and H. L. W. Chan, Lab Chip, 2012, 12, 3983 DOI: 10.1039/C2LC40428A

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