A novel approach in revealing mechanisms and particular step predictors of pH dependent tartrazine catalytic degradation in presence of Oxone®

Popadić, Marko; Marinović, Sanja; Mudrinić, Tihana; Milutinović-Nikolić, A.; Banković, Predrag; Đorđević, Ivana; Janjić, Goran V.

doi:10.1016/j.chemosphere.2021.130806

Cited by 12 publications

(9 citation statements)

References 33 publications

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“…The second possibility is the cleavage of the N=N azo bond by the attack of •OH (Figure 12c) to form the structures ( 7) and ( 8) in agreement with Ali et al [63]. In addition, according to Popadić et al [62], the catalytic degradation of tartrazine follows different pathways as a function of the solution pH; at pH = 6, the dominant mechanism follows a pathway including the attack of •OH radical, suggesting that the existence of a hydrogen atom bound to a diazo group is an essential prerequisite for the radical cleavage of diazo compounds. In the present study, tartrazine is in equilibrium with the protonated form (solution pH ca.…”

Section: Discussionsupporting

confidence: 84%

“…This mechanism agrees with theoretical density functional theory studies reported by Mendoza-Huizar [64], who reported that if a nucleophilic attack is considered as initial attack, it is necessary a second attack by free S-based radicals or electrophiles such as superoxide radical (•O 2 -) to cleave the N=N bond. However, the formation of this S-based radical is only promoted at basic pH of solution [62], and the scavenger tests from Figure 11 show the formation of •O 2-is negligible in our case. All this confirms that the dominant mechanism for the degradation of tartrazine in Cu4-800-N2 catalyst involves successive attacks of •OH radical.…”

Section: Discussionmentioning

confidence: 45%

“…Accordingly, it can be proposed that in the present experimental conditions, the photodegradation of yellow 5 mainly occurred by the attack of •OH radicals as discussed as follows. Figure 12 shows two different proposed pathways for the degradation of yellow 5 on the basis of the scavenger tests, and compares to the results reported in the literature [62][63][64]. The first pathway proceeds through the cleavage of C-N bond (Figure 12b) due to the attack of both superoxide radical (•O2-) and hydroxyl radical (•OH) to form structures (3) and ( 4), which may suffer a successive attack of •OH to form the structures ( 5) and ( 6) and molecular N2.…”

Section: Discussionmentioning

confidence: 71%

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Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

et al. 2022

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Carbon-doped nanostructured CuMo-based photocatalysts were prepared by solvothermal synthesis. Two thermal treatments—oxidative and inert atmosphere—were used for the synthesis of the catalysts, and the influence of spherical carbon structures upon the crystalline phases on the photocatalytic activity and stability was studied. XRD showed the catalysts are nanostructured and composed by a mixture of copper (Cu, Cu2O, and CuO) and molybdenum (MoO2 and MoO3) crystalline phases. The catalysts were used for the degradation of yellow 5 under solar light. A remarkable leaching of Mo both in dark and under solar irradiation was observed and quantified. This phenomenon was responsible for the loss of photocatalytic activity for the degradation of the dye on the Mo-containing series. Conversely, the Cu-based photocatalysts were stable, with no leaching observed after 6 h irradiation and with a higher conversion of yellow 5 compared with the Mo- and CuMo series. The stability of Cu-based catalysts was attributed to a protective effect of spherical carbon structures formed during the solvothermal synthesis. Regarding the catalysts’ composition, sample Cu4-800-N2 prepared by pyrolysis exhibited up to 4.4 times higher photoactivity than that of the pristine material, which is attributed to a combined effect of an enhanced surface area and micropore volume generated during the pyrolytic treatment due to the presence of the carbon component in the catalyst. Scavenger tests have revealed that the mechanism for tartrazine degradation on irradiated Cu-based catalysts involves successive attacks of •OH radicals.

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Section: Discussionsupporting

confidence: 84%

Section: Discussionmentioning

confidence: 45%

Section: Discussionmentioning

confidence: 71%

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Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

et al. 2022

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“…This mechanism agrees with other studies reported in the literature based on experimental and computational methods [52], proposing the nucleophilic attack of the N=N bond as the initial step. Popadić et al [50] and Ali et al [51] also reported that the catalytic degradation of tartrazine follows different pathways as a function of the pH of solution, including the attack of •OH radicals at slight acidic pH. This is in agreement with our results, since the photocatalytic assays have been carried out at pH 5.…”

Section: Investigation Of the Mechanismsupporting

confidence: 92%

Performance of a C-containing Cu-based photocatalyst for the degradation of tartrazine: Comparison of performance in a slurry and CPC photoreactor under artificial and natural solar light

Muñoz-Flores

Poon

Ania

et al. 2022

Journal of Colloid and Interface Science

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“…This is due to the existence of a wide range of electronic states, whose shares in the resulting spectrum are changing during redox transformations. There are several methods for deconvolution (peak fitting) of complex electronic absorption spectra, including use of Gaussian and/or Lorentzian approximations of the shapes of individual absorption bands [ 41 ] and Matrix Rank Analysis [ 42 ]. However, the number and shapes of the approximated individual absorption bands used for this deconvolution are usually chosen in a voluntary way.…”

Section: Spectroelectrochemical Methodsmentioning

confidence: 99%

Spectroelectrochemistry of Electroactive Polymer Composite Materials

Грибкова

Некрасов

2022

Polymers

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In this review, we have summarized the main advantages of the method of spectroelectrochemistry as applied to recent studies on electrosynthesis and redox processes of electroactive polymer composite materials, which have found wide application in designing organic optoelectronic devices, batteries and sensors. These polymer composites include electroactive polymer complexes with large unmovable dopant anions such as polymer electrolytes, organic dyes, cyclodextrins, poly(β-hydroxyethers), as well as polymer-inorganic nanocomposites. The spectroelectrochemical methods reviewed include in situ electron absorption, Raman, infrared and electron spin resonance spectroscopies.

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A novel approach in revealing mechanisms and particular step predictors of pH dependent tartrazine catalytic degradation in presence of Oxone®

Cited by 12 publications

References 33 publications

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Photocatalytic Performance of Carbon-Containing CuMo-Based Catalysts under Sunlight Illumination

Performance of a C-containing Cu-based photocatalyst for the degradation of tartrazine: Comparison of performance in a slurry and CPC photoreactor under artificial and natural solar light

Spectroelectrochemistry of Electroactive Polymer Composite Materials

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