Y H Wang

Publications (2)3.21 Total impact

• Source

  Available from: hku.hk

  Article: Electrochemical degradation of 4-chlorophenol at nickel-antimony doped tin oxide electrode.

  Y H Wang, K Y Chan, X Y Li, S K So
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  ABSTRACT: The effectiveness of a novel nickel-antimony doped tin oxide electrode for electrochemical degradation of organic pollutants was investigated using 4-chlorophenol (4-CP) as a model toxic organic. The experimental results demonstrate that the optimal Ni content was at Ni:Sn=1:500 in atomic ratio in the precursor coating solution, whereas the Sb:Sn ratio was set at 8:500. Using the electrode prepared with the optimal Ni doping ratio for 4-CP degradation, the charge-based efficiencies were up to 89 microg C(-1) for 4-CP destruction and 15 microg C(-1) for TOC removal, which were considerably higher than the efficiencies observed for other electrodes. It is suggested that the enhancement of the electrode for electrochemical oxidation of organics could be attributed to the production of hydroxyl radicals in anodic water electrolysis.
  Chemosphere 12/2006; 65(7):1087-93. · 3.21 Impact Factor
• Article: Electrochemical degradation of 4-chlorophenol at nickel–antimony doped tin oxide electrode

  Y.H. Wang, K.Y. Chan, X.Y. Li, S.K. So
  [show abstract] [hide abstract]
  ABSTRACT: The effectiveness of a novel nickel–antimony doped tin oxide electrode for electrochemical degradation of organic pollutants was investigated using 4-chlorophenol (4-CP) as a model toxic organic. The experimental results demonstrate that the optimal Ni content was at Ni:Sn = 1:500 in atomic ratio in the precursor coating solution, whereas the Sb:Sn ratio was set at 8:500. Using the electrode prepared with the optimal Ni doping ratio for 4-CP degradation, the charge-based efficiencies were up to 89 μg C−1 for 4-CP destruction and 15 μg C−1 for TOC removal, which were considerably higher than the efficiencies observed for other electrodes. It is suggested that the enhancement of the electrode for electrochemical oxidation of organics could be attributed to the production of hydroxyl radicals in anodic water electrolysis.
  Chemosphere.