Abstract
The photodegradation process of m-cresol (3-methylphenol), induced by Fe(III)-Cit complex, was investigated upon irradiation at 365 nm in natural water. The composition and photochemical properties of Fe(III)-Cit complex were studied by UV-Visible absorption spectrophotometer for optimizing the stoichiometry of the complex and photolysis under irradiation at 365 nm, respectively. A dark investigation of the system was performed before studying the photochemical behavior. The photooxidation efficiencies of m-cresol were dependent on the pH value, optimized at pH 2.86, oxygen, initial concentrations of Fe(III)-Cit complex, and m-cresol. Additionally, to look into the mechanism of m-cresol degradation using Fe(III)-Cit, tertiobutanol alcohol was used as scavenger for hydroxyl radicals and the result suggested that hydroxyl radical attack was the main pathway of m-cresol degradation. Besides, oxygen can enhance the photolysis of Fe(III)-Citrate complex by trapping the electron on the carbon centered radical formed after the photoredox process. Then O2•−formed reacts rapidly leading finally to formation of•OH radical. In absence of oxygen, less reactive species are formed; consequently the disappearance of m-cresol was strongly inhibited. Our work shows that the presence of Fe(III)-Citrate complex could have a considerable impact on the fate of organic pollutant in aquatic environment.
Highlights
Advanced oxidation technologies (AOTs) are innovative methods for water treatment, extremely useful in the case of substances resistant to conventional technologies [1, 2]
We demonstrated that Fe(III) were complexed by citric acid, the formation and composition of Fe(III)-Cit complex was first studied
With a stoichiometry 2 : 1 and the value of stability constant being β = 6.3 × 1019, this type of complexes could be formed in the natural aquatic environment due to the presence of citric acid and iron
Summary
Advanced oxidation technologies (AOTs) are innovative methods for water treatment, extremely useful in the case of substances resistant to conventional technologies [1, 2]. It was reported that light irradiation of Fe(III) complexes with dissolved organic matter (DOM) could produce both Fe(II) by the ligand-to-metal charge transfer (LMCT) reactions and H2O2 through the reduction of O2 by photoexcited DOM [3,4,5]. The efficiency of this photocatalytic process has already been observed to remove compound from water. Citric acid (C (OH)(COOH) (CH2COOH) 2, 2-hydroxy-propane-1,2,3-tricarboxylic acid, Cit) is used as model compound of several natural systems because of its presence in plants and soils
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