Priority pesticide dichlorvos removal from water by ozonation process: Reactivity, transformation products and associated toxicity

Priority pesticide dichlorvos removal from water by ozonation process: Reactivity, transformation products and associated toxicity

[Display omitted] •Dichlorvos exhibits moderate reactivity with molecular ozone.•Reaction between dichlorvos and formed hydroxyl radicals is fast.•Dimethyl phosphate, desmethyl dichlorvos, and dichloroacetic acid are the main TPs.•Indirect oxidation by OH guarantees dichlorvos and associated toxicit...

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Bibliographic Details
Published in:Separation and purification technology Vol. 192; pp. 123 - 129
Main Authors: Cruz-Alcalde, A., Sans, C., Esplugas, S.
Format: Journal Article
Language:English
Published: Elsevier B.V 09-02-2018
Subjects:
Dichlorvos
Hydroxyl radicals
Ozone oxidation
Second-order rate constants
Toxic intermediates
Dichlorvos
Hydroxyl radicals
Ozone oxidation
Second-order rate constants
Toxic intermediates
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Summary:[Display omitted] •Dichlorvos exhibits moderate reactivity with molecular ozone.•Reaction between dichlorvos and formed hydroxyl radicals is fast.•Dimethyl phosphate, desmethyl dichlorvos, and dichloroacetic acid are the main TPs.•Indirect oxidation by OH guarantees dichlorvos and associated toxicity abatement. The treatability of waters contaminated with priority pesticide dichlorvos (DDVP) by means of ozonation has been assessed for the first time. In order to do so, reaction kinetics, transformation mechanisms and associated toxicity have been inspected in detail. Second-order rate constants of DDVP reactions with O3 and OH were determined to be 590 and 2.2·109M−1s−1, respectively. These values partly explained the degradation profiles obtained during experiments with and without the presence of an OH scavenger, in which the significant contribution of the indirect degradative route in the removal of DDVP was revealed. LC-MS analyses for ozonated samples allowed the elucidation of desmethyl dichlorvos (d-DDVP), dichloroacetic acid (DCA) and dimethyl phosphate (DMP) as main transformation products (TPs). DMP was found to be present in both O3 and OH-mediated oxidation pathways. Three possible degradation routes were proposed for OH degradation, whereas the direct oxidation by O3 was only well-explained by the addition of this oxidant to the double bond of DDVP dichlorovinyl moiety. Microtox® bioassays revealed the inability of molecular ozone to reduce the toxicity of the medium and pointed out the importance of OH contribution in the degradation process. In general, ozonation could be a suitable treatment alternative for DDVP, formed TPs and associated toxicity abatement.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2017.09.069