Photocatalytic degradation of pesticide methomyl: determination of the reaction pathway and identification of intermediate products

Tamimi, Malika; Qourzal, Samir; Assabbane, Ali; Chovelon, Jean‐Marc; Ferronato, Corinne; Ait‐Ichou, Y.

doi:10.1039/b517105a

Cited by 77 publications

(51 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Moreover, taking into consideration the complex nature of photocatalysis and the wide variety of stable and unstable photoproducts that can be formed, rate of TOC reduction depended on the individual tested organophosphate. The same behavior has been observed in numerous irradiated pesticide solutions reported in the available literature; for instance, the formation and evolution of several carboxylic acids (such as formic, acetic, glycolic, and cyanuric acids) as transient intermediates of photocatalytic reaction, which could eventually undergo complete mineralization as irradiation progresses, have been published [4,5,9,21]. Formation of oxon derivatives (such as paraoxon ethyl, pirimiphos-oxon, fenthion-oxon), corresponding phenols (e.g., nitrophenol), various and different trialkyl and dialkyl phosphorothioate or phosphate esters, and quinonidal compounds has also been observed and detected as major intermediate photoproducts that subsequently underwent mineralization [5].…”

Section: Toc Contentmentioning

confidence: 49%

“…Nowadays, among the most promising and successful applications of heterogeneous photocatalysis applied for the removal of various toxicants from water, photocatalysis over titanium dioxide (TiO 2 ) is included, since it has been demonstrated as one of the most frequently used methodologies employed for the treatment of chlorinated phosphate esters and carbamic, thiocarbamic, and triazine pesticides [4][5][6][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Photocatalytic Degradation of Selected Organophosphorus Pesticides Using Titanium Dioxide and UV Light

Petsas¹,

Vagi²

2018

Titanium Dioxide - Material for a Sustainable Environment

View full text Add to dashboard Cite

The photocatalytic degradation of five selected organophosphorus pesticides (OPPs), azinphos methyl, azinphos ethyl, disulfoton, dimethoate, and fenthion, has been investigated using TiO 2 (photocatalyst) and UV irradiation. The addition of H 2 O 2 (oxidant agent) into the illuminated aquatic suspensions was also surveyed. The degradation kinetics was studied under different experimental conditions such as pesticides' and catalyst's concentration. Experiments were performed in a Pyrex UV laboratory-constructed photoreactor equipped with 4 × 18 W low-pressure Hg lamps emitting at 365 nm (maximum intensity 14.5 mW cm −2 at distance 15 cm). The concentration of pesticides was determined by GC-NPD means. The extent of pesticide mineralization was assessed through TOC measurements. The results demonstrated that photolysis of target organophosphates in the absence of catalyst or oxidant is a slow process resulting in incomplete mineralization. Contradictory, studied pollutants were effectively degraded in the presence of TiO 2 ; evolution of inorganic heteroatoms (SO 4 ) as final products provided evidence that pesticide deterioration occurred. The photolysis efficiencies decreased in the order: disulfoton > azinphos ethyl > azinphos methyl > fenthion > dimethoate. Furthermore, a synergistic effect was observed with the addition of H 2 O 2 in the pesticide-TiO 2 suspensions. In all cases examined, reduction process appeared to follow pseudo first-order kinetics (Langmuir-Hinshelwood model). In conclusion, both catalytic systems investigated (UV-TiO 2 and UV-TiO 2 -H 2 O 2 ) have good potential for small-scale applications.2

show abstract

Section: Toc Contentmentioning

confidence: 49%

Section: Introductionmentioning

confidence: 99%

Photocatalytic Degradation of Selected Organophosphorus Pesticides Using Titanium Dioxide and UV Light

Petsas¹,

Vagi²

2018

Titanium Dioxide - Material for a Sustainable Environment

View full text Add to dashboard Cite

show abstract

“…To illustrate, Malato et al ( 2002 ) found that methomyl solutions at either pH 2.7 or pH 5 did not signi fi cantly degrade via hydrolysis after 20 days; Tamimi et al ( 2006 ) later veri fi ed this result at pH 6 as well. The authors of both studies concluded that hydrolysis does not occur to any signi fi cant extent in the fi eld-at least under mildto-strong acidic conditions.…”

Section: Abiotic Processesmentioning

confidence: 76%

Environmental Fate and Toxicology of Methomyl

Scoy

Yue

Deng

et al. 2012

Reviews of Environmental Contamination and Toxicology

View full text Add to dashboard Cite

The insecticide methomyl, an oxime carbamate, was first introduced in 1968 for broad spectrum control of several insect classes, including Lepidoptera, Hemiptera, Homoptera, Diptera, and Coleoptera. Like other carbamates, it inhibits AChE activity, resulting in nerve and/or tissue failure and possibly death. Considered highly toxic to insects (larval and adult stages), methomyl is thought to be metabolically degraded via mixed-function oxidase(s). Methomyl has both a low vapor pressure and Henry's law constant; hence, volatilization is not a major dissipation route from either water or moist or dry soils. Photolysis represents a minor dissipation pathway; however, under catalytic conditions, degradation via photolysis does occur. Methomyl possesses a moderate-to-high water solubility; thus hydrolysis, under alkaline conditions, represents a major degradation pathway. Methomyl has a low-to-moderate sorption capacity to soil. Although results may vary with soil type and organic matter content, methomyl is unlikely to persist in complex soils. Methomyl is more rapidly degraded by microbes, and bacterial species have been identified that are capable of using methomyl as a carbon and/or nitrogen source. The main degradation products of methomyl from both abiotic and biotic processes are methomyl oxime, acetonitrile, and CO₂. Methomyl is moderately to highly toxic to fishes and very highly toxic to aquatic invertebrates. Methomyl is highly toxic orally to birds and mammals. Methomyl is classed as being highly toxic to humans via oral exposures, moderately toxic via inhalation, and slightly toxic via dermal exposure. At relatively high doses, it can be fatal to humans. Although methomyl has been widely used to treat field crops and has high water solubility, it has only infrequently been detected as a contaminant of water bodies in the USA. It is classified as a restricted-use insecticide because of its toxicity to multiple nontarget species. To prevent nontarget species toxicity or the possibility of contamination, as with all pesticides, great care should be taken when applying methomyl-containing products for agricultural, residential, or other uses.

show abstract

“…A brief summary showing the starting material and by-products under photolytic condition is shown below in Chart 2. Konstantinou et al, 2001a;Pelizzetti et al, 1990Pelizzetti et al, , 1992aPelizzetti et al, , 1992bMinero et al, 1996;Muszkat et al, 1995;Sanlaville et al, 1996, Sleiman et al, 2006 Aniline and Amide derivative Amines, Dechlorinated, Dealkylated, Cyclized, Aliphatics, Cyclized Konstantinou et al, 2001bKonstantinou et al, , 2002Sakkas et al, 2004;Peñuela and Barceló, 1996;Pathirana & Maithreepala, 1997 7 Thicarbamate derivative Amine, Carboxy, Sulfoxide, Dealkylated Vidal et al, 1999;Sturini et al, 1996;Vidal & Martin, 2001 8 Phenoxy-acids derivatives Hydroxylated, Carboxylated, Chlorophenols, Quinonidal Herrmann et al, 1998;Topalov et al, 2000;Barbeni et al, 1987;Poulios et al, 1998;9 Organophosphorus derivatives Hydroxy, Oxon, Phenol, Dialkylated, Trialkyl esters, Fragmented products Herrmann, 1999;Konstantinou et al, 2001a, Oncescu et al, 2010Herrmann et al, 1999;Hua et al, 1995;Sakkas et al, 2002;Dominguez et al, 1998 10 Carbamate derivative Hydroxylated, Decarboxylated, Phenolic, Dealkylated, Cyclized Tamimi et al, 2006;Percerancier et al, 1995;Pramauro et al, 1997;Tanaka et al, 1999;Marinas et al, 2001;Bianco Prevot et al, 199...…”

Section: Characterization Of Intermediate Productsmentioning

confidence: 99%