1. A comparison between flow-through cathode and mixed tank cells for the electro-Fenton process with conductive diamond anode.
- Author
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Moraleda I, Oturan N, Saez C, Llanos J, Rodrigo MA, and Oturan MA
- Subjects
- Boron chemistry, Bromouracil analysis, Carbon chemistry, Electric Conductivity, Iron chemistry, Oxidation-Reduction, Bromouracil analogs & derivatives, Diamond chemistry, Hydrogen Peroxide chemical synthesis, Wastewater chemistry, Water Pollutants, Chemical analysis
- Abstract
This work focusses on the production of hydrogen peroxide and in the removal of bromacil by the electro-Fenton process using two different electrochemical cells: mixed tank cell (MTC) and flow-through cell (FTC). Both cells use boron doped diamond (BDD) as anode and carbon felt as cathode to promote the formation of hydrogen peroxide. In the case of the MTC, two surface area ratios, A
cathode /Aanode , have been used. Results show that the H2 O2 produced by MTC and FTCPSC increases with the time until a stabilization state. For the FTCPSC, the average hydrogen peroxide concentration produced increases progressively with the current, while for MTC the maximum values are found in applying very low current densities. In addition, the FTCPSC provides higher concentrations of hydrogen peroxide for the same current density applied. Regarding the MTC, it can be stated that the higher the area of the cathode, the higher is the amount of H2 O2 produced and the lower is the cell voltage (because of a more efficient current lines distribution). The initial oxidation of bromacil is very efficiently attained being rapidly depleted from wastewater. However, the higher production of hydrogen peroxide obtained by the FTCPSC cell does not reflect on a better performance of the electro-Fenton process. Thus, bromacil is better mineralized using the MTC cell with the lowest cathode area. This observation has been explained because larger concentrations of produced hydrogen peroxide seems to benefit the oxidation of intermediates and not the mineralization., (Copyright © 2019 Elsevier Ltd. All rights reserved.)- Published
- 2020
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