2012
DOI: 10.1016/j.pecs.2012.01.002
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Determination of toxic products released in combustion of pesticides

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Cited by 28 publications
(15 citation statements)
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“…Repeatability and reproducibility of data count among the major advantages of the equipment 37 together with its capacity of revealing atypical fire phenomena, like-liquid phase decomposition process of organophosphorous pesticides. 38 In particular, parametric tests on product samples of about 50 g under controlled air intake allow for characterizing fire behaviour of the studied material or product (liquid, solids, gases) on the full spectrum of fire conditions (fuel rich or fuel lean). Scientific-sound diagnosis of the fire behaviour of materials is achieved thanks to the access to key measures such as mass loss, HRR by application of fire calorimetry laws based on the assessment of oxygen consumption (OC) 39 and carbon dioxide generation (CDG), 40 measurements of fire effluent concentrations and related emission yields allowing for an evaluation of pollutants and fire toxicity issues.…”
Section: Fire Propagation Apparatus (Tewarson Calorimetry)mentioning
confidence: 99%
“…Repeatability and reproducibility of data count among the major advantages of the equipment 37 together with its capacity of revealing atypical fire phenomena, like-liquid phase decomposition process of organophosphorous pesticides. 38 In particular, parametric tests on product samples of about 50 g under controlled air intake allow for characterizing fire behaviour of the studied material or product (liquid, solids, gases) on the full spectrum of fire conditions (fuel rich or fuel lean). Scientific-sound diagnosis of the fire behaviour of materials is achieved thanks to the access to key measures such as mass loss, HRR by application of fire calorimetry laws based on the assessment of oxygen consumption (OC) 39 and carbon dioxide generation (CDG), 40 measurements of fire effluent concentrations and related emission yields allowing for an evaluation of pollutants and fire toxicity issues.…”
Section: Fire Propagation Apparatus (Tewarson Calorimetry)mentioning
confidence: 99%
“…Production, storage and wide use of pesticides can cause accidental fires in storage facilities, while contaminated plant matter subjected to wildfire provides thermal decomposition and additional pathways for generating toxic products [7][8][9][10][11]. The available literature on thermal decomposition and combustion of pesticides [8,[12][13][14][15][16][17] reports different burning behavior and patterns of thermal decomposition. Specifically, pesticides with complex aromatic structure exhibit below 300°C melt, evaporate and experience the first pyrolysis process with formation of heavy substances.…”
Section: Introductionmentioning
confidence: 99%
“…The obtained results led to the conclusion that in the gaseous products the organic compounds, polycyclic aromatic hydrocarbons and halogenated aromatic hydrocarbons were present. Different techniques could be employed to determine thermal decomposition of pesticides and identify released toxic products [8]. Recently, thermal decomposition of the pesticide was also studied using density functional methods [21].…”
Section: Introductionmentioning
confidence: 99%
“…5 In addition to the dissemination of pesticides in the environment, toxic products can be released from unintentional combustion of such chemicals in the case of accidental fire or burning of treated biomass. 6 These highly poisonous species belong to various organophosphorus families like phosphine oxides (OPR 3 ), phosphinates (OP(OR)R 2 ), phosphonates (OP(OR) 2 R), and phosphates (OP(OR) 3 ). Each compound is characterized by the R groups, which can be an alkyl chain, a sulfur group (e.g., in VX), an amine (e.g., in phenamiphos), a cyano group (e.g., in tabun), or a fluorine atom (e.g., in sarin and soman).…”
Section: ■ Introductionmentioning
confidence: 99%