Intensification of the Fenton Process by Increasing the Temperature

Zazo, Juan A.; Pliego, Gema; Blasco, Sonia; Casas, José A.; Rodrı́guez, Juan J.

doi:10.1021/ie101963k

Cited by 166 publications

(88 citation statements)

References 34 publications

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“…It has to be highlighted the potential of magnetite as CWPO catalyst under the testing conditions due to its high activity and remarkable stability. Moreover, the mineralization percentage achieved was even higher than the obtained upon homogeneous Fenton oxidation under similar working conditions [27].…”

Section: Magnetic Natural Mineralsmentioning

confidence: 69%

“…A slight decrease of catalytic activity was observed upon three consecutive runs, which was attributed to small leaching of iron from the solid. Despite the fact that several magnetic minerals have shown to be fairly stable in the process, the degradation rates observed are still far from those of homogeneous Fenton oxidation under similar operating conditions [27]. With the aim of improving the activity of the catalysts and thus, increasing the oxidation rate, the effect of including other metals into the magnetite structure by isomorphic substitution of Fe has been studied by several authors [37-39, 57, 58] were directly related to the amount of iron leached, which decreased upon the three successive runs (13, 6 and 4 mg L -1 measured in the liquid phase).…”

Section: Magnetic Natural Mineralsmentioning

confidence: 94%

“…(1-2)), being commonly used 1 part of iron per 4-25 parts of hydrogen peroxide (w/w) [24], while the optimum dose of oxidant is frequently the stoichiometric amount for complete oxidation, namely mineralization [25,26]. Although most of the works dealing with Fenton oxidation have been carried out at mild conditions, Zazo et al, (2011) [27] have recently demonstrated that increasing the temperature, up to 120 ºC, clearly improves both the oxidation rate and the degree of mineralization of the pollutants. The Fenton effluent is finally neutralized with NaOH, and thus iron complexes precipitates as Fe(OH) 3 .…”

Section: The Fenton Processmentioning

confidence: 99%

See 2 more Smart Citations

Preparation of magnetite-based catalysts and their application in heterogeneous Fenton oxidation – A review

Muñoz

Pedro

Casas

et al. 2015

Applied Catalysis B: Environmental

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268

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Esta es la versión de autor del artículo publicado en: This is an author produced version of a paper published in: AbstractThis study presents a critical review on the application of magnetite-based catalysts to industrial wastewater decontamination by heterogeneous Fenton oxidation. The use of magnetic materials in this field started only around 2008 and continues growing increasingly year by year. The potential of these materials derives from their higher ability for degradation of recalcitrant pollutants compared to the conventional iron-supported catalysts due to the presence of both Fe(II) and Fe(III) species. In addition, their magnetic properties allow their easy, fast and inexpensive separation from the reaction medium. The magnetic materials applied up to now can be classified in three general groups: magnetic natural minerals, in-situ-produced magnetic materials and ferromagnetic nanoparticles. A survey of the catalysts investigated so far is presented paying attention to their nature and competitive features in terms of activity and durability.2

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Section: Magnetic Natural Mineralsmentioning

confidence: 69%

Section: Magnetic Natural Mineralsmentioning

confidence: 94%

Section: The Fenton Processmentioning

confidence: 99%

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Preparation of magnetite-based catalysts and their application in heterogeneous Fenton oxidation – A review

Muñoz

Pedro

Casas

et al. 2015

Applied Catalysis B: Environmental

Self Cite

626

268

View full text Add to dashboard Cite

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“…All the acids were mineralized except oxalic which showed to be refractory to Fenton oxidation even at those higher temperatures. Zazo et al [40] reported that oxalic acid can be mineralized upon Fenton oxidation at around 100°C. Fig.…”

Section: Oxidation Byproductsmentioning

confidence: 99%

Triclosan breakdown by Fenton-like oxidation

Muñoz

Pedro

Casas

et al. 2012

Chemical Engineering Journal

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Fenton-like oxidation has proved to be highly efficient for the removal of triclosan, a highly toxic emerging water pollutant. From 10mg/L starting aqueous solutions complete conversion of triclosan was achieved in less than 1h at 25°C and around 20min at 50°C with 1mg/L Fe3+ and H2O2 at the theoretical stoichiometric amount (25mg/L). From the evolution of byproducts a reaction pathway has been proposed according to which oxidation of triclosan gives rise to several aromatic intermediates (mainly, p-hydroquinone of triclosan and 2,4-dichlorophenol) which evolve to short-chain organic acids. These compounds are mineralized except oxalic acid. A dramatic decrease of ecotoxicity was achieved in a relatively short time (more than 95% in 15min at 35°C). The evolution of ecotoxicity is intimately related to the disappearance of triclosan, much more toxic than the aromatic oxidation intermediates. This disappearance was successfully described by a simple pseudo-first order rate equation with an apparent activation energy value close to 27kJ/mol. The apparent rate constant at 25°C was several orders of magnitude higher than the reported in the literature for other chlorophenolic compounds indicating a higher susceptibility of triclosan to OH radical attackThis research has been supported by the Spanish MICINN through the project CTQ2008-03988 and by the CM through the project S-2009/AMB-158

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“…Currently, many technologies have been developed to improve Fenton oxidation for removing organic contaminants from aqueous solutions, such as photo-assisted (Al Momani et al, 2006;Kusic et al, 2006;Lau et al, 2002), microwave-enhanced (Liu et al, 2013;Yang et al, 2009), heating (Pliego et al, 2012;Zazo et al, 2011), and quinone (Chen and Pignatello, 1997;Gomez-Toribio et al, 2009) and hydroxylamine hydrochloride (HA) (Chen et al, 2011) redox cycling. As mentioned above, a major drawback of the Fenton system has been the accumulation and hydrolysisprecipitation of ferric ions, which could further slow down the whole Fenton process.…”

Section: Introductionmentioning

confidence: 99%