Degradation of the Dye Reactive Blue 4 by Coupled Photoassisted Electrochemistry at DSA<sup>®</sup>-Type Electrode

Silva, Rodrigo G. da; Andrade, Adalgisa R. de

doi:10.5935/0103-5053.20150338

Cited by 8 publications

(7 citation statements)

References 27 publications

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“…In comparison to other electrodes, DSAs have high chemical and mechanical, and higher current density. Many workers have been used DSA as an efficient material for degradation of glyphosate formulations [24], Reactive Blue 4 [25], Methyl orange [26] and mixtures of phenol-formaldehyde [27]. In these studies, the efficiency depended on several parameters, like pollutant concentration, initial pH, supporting electrolyte, cathode material, current density and temperature.…”

Section: Introductionmentioning

confidence: 99%

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Baddouh

Bessegato

Rguiti

et al. 2018

Journal of Environmental Chemical Engineering

104

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A B S T R A C TSurface water contamination by dyes released from a variety of industries is an environmental problem of great concern. However, electrochemical oxidation is a promising alternative for water treatment. In this paper, we studied the electrochemical oxidation of Rhodamine B (RhB) dye on the Ti/RuO 2 -IrO 2 (DSA ® ) and SnO 2 anodes comparing their efficiencies. The effect of some parameters, such as current density, initial pH (pH 0 ), nature, concentration of electrolyte and temperature at the electrochemical oxidation was investigated evaluating the decolorization and the chemical oxygen demand (COD) removal at optimal conditions. Complete decolorization of RhB was achieved in the presence of chloride ions at different times using both electrodes. An optimum efficiency was obtained at pH 6.5, T = 25°C. Also, the current density of 40 mA cm −2 using the DSA electrode in NaCl 0.05 mol L −1 + Na 2 SO 4 0.1 mol L −1 mixture solution as a supporting electrolyte, 100% color removal and 61.7% chemical oxygen demand removal after 90 min of electrolysis were achieved. DSA showed better performance than SnO 2 in wide operating conditions and was proved to be more cost-effective and more efficient. The effectiveness of the degradation is explained by indirect electrochemical oxidation, where in the presence of chlorides electrolyte leads to the electro-generation of strong oxidant species, such as Cl 2 and ClO − ions, improving the efficiency of treatment at both electrodes.The DSA has been classified as 'active' or 'non-active' depending on

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Section: Introductionmentioning

confidence: 99%

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Baddouh

Bessegato

Rguiti

et al. 2018

Journal of Environmental Chemical Engineering

104

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“…This shows the lack of control over the dye degradation reactions and the existence of spontaneous reactions that can lead to the same lower fragments via multiple paths. , With regards to the auxiliary groups present on the dye structures (such as amino-groups, sulfone-groups, halogen-groups), mapping down their degradation pathway was more difficult. Research examples either did not identify further degradation past the original rupture from the dye structure, ,, or identified big fragments and even polymerized by-products …”

Section: On the Degradation Pathway Of Anthraquinone Dyesmentioning

confidence: 99%

“…These fragments were mainly produced by the cleavage and subsequent degradation of the anthraquinone ring through various steps. In some cases it was noted that different dyes (Reactive Blue 19 213 and Reactive Blue 4 214 ) treated with the same method led to the same degradation products (as derived by the AQ ring). This observation could be an indication of some control over the end products if a specific method is applied.…”

Section: On the Degradation Pathway Of Anthraquinone Dyesmentioning

confidence: 99%

Degradation of Anthraquinone Dyes from Effluents: A Review Focusing on Enzymatic Dye Degradation with Industrial Potential

Routoula

Patwardhan

2020

Environ. Sci. Technol.

393

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Up to 84 000 tons of dye can be lost in water, and 90 million tons of water are attributed annually to dye production and their application, mainly in the textile and leather industry, making the dyestuff industry responsible for up to 20% of the industrial water pollution. The majority of dyes industrially used today are aromatic compounds with complex, reinforced structures, with anthraquinone dyes being the second largest produced in terms of volume. Despite the progress on decolorization and degradation of azo dyes, very little attention has been given to anthraquinone dyes. Anthraquinone dyes pose a serious environmental problem as their reinforced structure makes them difficult to degrade naturally. Existing methods of decolorization might be effective but are neither efficient nor practical due to extended time, space, and cost requirements. Attention should be given to the emerging routes for dye decolorization via the enzymatic action of oxidoreductases, which have already a strong presence in various other bioremediation applications. This review will discusses the presence of anthraquinone dyes in the effluents and ways for their remediation from dyehouse effluents, focusing on enzymatic processes.

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“…Structurally, RB4 consists of a dichlorotriazine group and anthraquinone chromophore. Due to its high water solubility and low biodegradability, wastewater treatment is required in processes using this dye [5,6].…”

Section: Introductionmentioning

confidence: 99%

Application of impregnated biocarbon produced from soybean hulls in dye decolorization

Kulic-Mandic

Bečelić‐Tomin

Pucar-Milidrag

et al. 2021

Hem Ind

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Waste soybean hulls (WSH) were investigated as a Fe-support in two forms: raw and carbonized (i.e. biocarbon, BC), as possible value-added materials. Fe-impregnation was implemented in order to produce heterogeneous Fenton catalysts for Reactive Blue 4 dye degradation. Materials characterization demonstrated a rise in the specific surface area due to decomposition of WSH constituents during carbonization (to obtain BC) and thermal activation (to obtain Fe-WSH and Fe-BC), thus producing catalysts with high mesoporosity and hematite as the active site for Fenton reaction. Among the investigated materials, Fe-WSH showed the greatest ability for ?OH production in acidic medium. Next, the heterogeneous Fenton process was optimized by using response surface methodology, which resulted in selection of the following reaction conditions: 3 mM H2O2, 100 mg Fe-WSH, reaction time of 180 min, at a constant pH 3, RB4 concentration of 50 mg dm-3 and at room temperature. The achieved dye removal and mineralization were 85.7 and 66.8 %, respectively, while the catalyst showed high stability and the reaction intermediates formed during the oxidation process had a low inhibitory effect on Vibrio fischeri bacteria.

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Degradation of the Dye Reactive Blue 4 by Coupled Photoassisted Electrochemistry at DSA^®-Type Electrode

Cited by 8 publications

References 27 publications

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Degradation of Anthraquinone Dyes from Effluents: A Review Focusing on Enzymatic Dye Degradation with Industrial Potential

Application of impregnated biocarbon produced from soybean hulls in dye decolorization

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Degradation of the Dye Reactive Blue 4 by Coupled Photoassisted Electrochemistry at DSA®-Type Electrode

Cited by 8 publications

References 27 publications

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Electrochemical decolorization of Rhodamine B dye: Influence of anode material, chloride concentration and current density

Degradation of Anthraquinone Dyes from Effluents: A Review Focusing on Enzymatic Dye Degradation with Industrial Potential

Application of impregnated biocarbon produced from soybean hulls in dye decolorization

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Degradation of the Dye Reactive Blue 4 by Coupled Photoassisted Electrochemistry at DSA^®-Type Electrode