Diazo dye Congo Red degradation using a Boron-doped diamond anode: An experimental study on the effect of supporting electrolytes

Jalife-Jacobo, H.; Feria-Reyes, Rossy; Serrano-Torres, Oracio; Gutiérrez-Granados, Silvia; Peralta‐Hernández, Juan M.

doi:10.1016/j.jhazmat.2016.02.056

Cited by 83 publications

(26 citation statements)

References 38 publications

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“…Sulfate, chloride, and nitrate solutions are often used as supporting electrolytes in the electrochemical oxidation processes . Figure b shows the results obtained in the photo‐electrolysis process with different electrolytes.…”

Section: Resultsmentioning

confidence: 99%

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Zhu

Dong

Zhou

2018

CLEAN Soil Air Water

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Electrochemical oxidation has drawn considerable research attention for the destruction of organic contaminants. This study utilizes the combination of electrolysis and the UV photolysis process to degrade the β‐blocker atenolol (ATL). The results show that the combination of electrolysis and UV photolysis is superior to a single process alone based on the removal rates of ATL and electrical efficiency per order (EE/O). In situ electrogenerated chlorine is confirmed to be responsible for ATL degradation with NaCl electrolytes, and mixed metal oxide (MMO) anodes play a more significant role in the generation of active chlorine than platinum (Pt) anodes. Moreover, reactive species (hydroxyl radical •OH and chlorine radical •Cl) mainly contributed to ATL degradation during the photo‐electrolysis process. Increasing the concentration of NaCl electrolytes and applied current densities can enhance the ATL degradation. Finally, major intermediate products are identified, and a possible degradation pathway of ATL is proposed during the photo‐electrolysis processes. This study demonstrate that the photo‐electrolysis process can be considered as a potential technology for the destruction of pharmaceutical pollutants in water.

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Section: Resultsmentioning

confidence: 99%

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Zhu

Dong

Zhou

2018

CLEAN Soil Air Water

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“…Pseudo-first-order kinetic constants (k 1 ) and corresponding square of the correlation coefficient (R 2 ) for decolorizations of OII and SY at λ max = 484 and 482 nm, respectively, by EF and PEF processes with different initial concentrations of Fe 2+ + . 22,[41][42][43][44][45] Normally, NO 3 is formed in the greatest quantity. 22,[41][42][43][44][45] Thus, we consider the mineralization of OII and SY as their conversion into CO 2 with the release of NO 3 and SO 4 2as major inorganic ions, according to equations 17 and 18, respectively.…”

Section: Mineralization Of Oii and Sy Solutionsmentioning

confidence: 99%

Hydrogen Peroxide Electrogeneration by Gas Diffusion Electrode Modified With Tungsten Oxide Nanoparticles for Degradation of Orange II and Sunset Yellow FCF Azo Dyes

Paz

Pinheiro

Aveiro

et al. 2019

J. Braz. Chem. Soc.

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In this work, the gas diffusion electrode (GDE) cathode of Vulcan XC72 carbon modified with nanoparticles of WO 2.72 (WO 2.72 / Vulcan XC72) was used for H 2 O 2 electrogeneration and degradation of 350 mL of Orange II (OII) and Sunset Yellow FCF (SY) azo dyes by electro-Fenton (EF) and photoelectro-Fenton (PEF) processes with different Fe 2+ initial content (1.00, 0.50 and 0.25 mmol L-1). The WO 2.72 / Vulcan XC72 GDE electrolyzed approximately 3 times more H 2 O 2 than the Vulcan XC72 GDE. Decolorizations and mineralizations of the dye solutions were more efficient at higher concentrations of Fe 2+. The decolorization decay showed pseudo-first-order kinetics. The most promising decolorization results obtained at processes of WO 2.72 / Vulcan XC72 cathode combined with Pt anode (100% color removal of OII and SY at 30 and 20 min of electrolysis with 1.00 mmol L-1 Fe 2+ , respectively). The best mineralization achieved in trials of WO 2.72 / Vulcan XC72 cathode combined with boron-doped diamond (BDD) anode (82% total organic carbon (TOC) removal of OII by PEF / 1.00 after 3 h and 90% TOC removal of SY by PEF / 0.50 after 4 h). It was found that SY decolorization was faster and mineralization showed a similar yield independent of oxidized dye.

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“…Electrochemical oxidation has been reported with different anodes, including dense and porous materials. Dense materials, such as metal electrodes, [7][8][9] metal oxide electrodes (PbO 2 , Bi 2 O 5 -PbO 5 , IrO 2 and SnO 2 ), 10,11 borondoped diamond (BDD) electrodes [12][13][14][15] and dimensionally stable anodes (DSA, i.e., Ti/IrO 2 , Ti/RuO 2 and Ti/SnO 2 ), 16 have attracted interest from many researchers because of their improved conductivity and catalytic activity. Porous electrodes, such as active carbon bres, 17 carbon nanotubes 18 and other porous materials, [19][20][21][22][23][24][25] have been proposed as a result of their high specic surface areas, electrical conductivity and chemical resistance.…”

Section: Introductionmentioning

confidence: 99%

Anti-corrosion porous RuO₂/NbC anodes for the electrochemical oxidation of phenol

Qin

Wei

et al. 2019

RSC Adv.

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Diazo dye Congo Red degradation using a Boron-doped diamond anode: An experimental study on the effect of supporting electrolytes

Cited by 83 publications

References 38 publications

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Hydrogen Peroxide Electrogeneration by Gas Diffusion Electrode Modified With Tungsten Oxide Nanoparticles for Degradation of Orange II and Sunset Yellow FCF Azo Dyes

Anti-corrosion porous RuO₂/NbC anodes for the electrochemical oxidation of phenol

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Diazo dye Congo Red degradation using a Boron-doped diamond anode: An experimental study on the effect of supporting electrolytes

Cited by 83 publications

References 38 publications

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Degradation of Atenolol with Electrochemical Oxidation at Mixed Metal Oxide Electrodes Assisted by UV Photolysis

Hydrogen Peroxide Electrogeneration by Gas Diffusion Electrode Modified With Tungsten Oxide Nanoparticles for Degradation of Orange II and Sunset Yellow FCF Azo Dyes

Anti-corrosion porous RuO2/NbC anodes for the electrochemical oxidation of phenol

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Anti-corrosion porous RuO₂/NbC anodes for the electrochemical oxidation of phenol