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Rapid prediction of hydrogen peroxide concentration eletrogenerated with boron doped diamond electrodes

  • Rubén F. Gutiérrez-Hernández EMAIL logo , Ricardo Bello-Mendoza , Javier F. Valle-Mora , Juan M. Peralta-Hernández , Edi A. Malo , Aracely Hernández-Ramírez and Hugo A. Nájera-Aguilar
Published/Copyright: August 2, 2017
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Journal of Advanced Oxidation Technologies
From the journal Journal of Advanced Oxidation Technologies Volume 20 Issue 2

Abstract

The electrochemical generation of hydrogen peroxide with boron doped diamond electrodes was experimentally investigated to assess the influence of basic operating parameters on H2O2 production rate. Experiments were conducted in an undivided electrolytic cell, at room temperature, and different operating conditions of air bubbling, stirring and current density. Current density was the most influencing parameter affecting H2O2 generation. Therefore, an equation was proposed to describe hydrogen peroxide generation at BDD electrodes as a function of current density and electrolysis time. Experimental data showed that H2O2 concentration significantly increased during the first 45 min of electrolysis, and thereafter it remained constant until the end of the reaction. The equation was able to describe well this H2O2 production pattern. Additional experiments were conducted to validate the proposed equation. Good agreement between theoretical predictions and experimental data, as assessed by the Chi square goodness of fit test, was observed.

Keywords: AOPs; BDD; H2O2 production rate; oxygen reduction; undivided electrolytic cell

Acknowledgement

R.F. Gutiérrez-Hernández gratefully acknowledges the scholarships provided by CONACyT and DGEST.

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Received: 2017-4-3
Revised: 2017-5-29
Accepted: 2017-6-2
Published Online: 2017-8-2

© 2017 by Walter De Gruyter GmbH and Sycamore Global Publications LLC

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https://doi.org/10.1515/jaots-2017-0037
Keywords for this article
AOPs; BDD; H2O2 production rate; oxygen reduction; undivided electrolytic cell

Articles in the same Issue

  2. Editorial
  4. Excitation Kinetics of Oxygen O(1D) State in Low-Pressure Oxygen Plasma and the Effect of Electron Energy Distribution Function
  6. Using amino-functionalized Fe3O4-WO3 nanoparticles for diazinon removal from synthetic and real water samples in presence of UV irradiation
  8. Treatment of high salinity wastewater using CWPO process for reuse
  10. Electrochemical Advanced Oxidation Processes (EAOP) to degrade per- and polyfluoroalkyl substances (PFASs)
  12. Effect of feedstock impurities on activity and selectivity of V-Mo-Nb-Te-Ox catalyst in ethane oxidative dehydrogenation
  14. Photocatalytic Degradation of Azo Dyes Over Semiconductors Supported on Polyethylene Terephthalate and Polystyrene Substrates
  16. Effects of calcination temperature on sol-gel synthesis of porous La2Ti2O7 photocatalyst on degradation of Reactive Brilliant Red X3B
  18. ClO2-oxidation-based demulsification of oil-water transition layer in oilfields: An experimental study
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  24. Degradation of imidacloprid insecticide in a binary mixture with propylene glycol by conventional fenton process
  26. Gemini surfactant-assisted synthesis of BiOBr with superior visible light-induced photocatalytic activity towards RhB degradation
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  34. Biosolubilization of low-grade rock phosphate by mixed thermophilic iron-oxidizing bacteria
  36. Degradation of methyl orange using dielectric barrier discharge water falling film reactor
  38. Rapid prediction of hydrogen peroxide concentration eletrogenerated with boron doped diamond electrodes
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