ChemicalBook Product Catalog Chemical pesticides Germicide Substituted benzene fungicide Chlorothalonil

Chlorothalonil

Chlorothalonil Basic information
Description uses References
Product Name:Chlorothalonil
Synonyms:tetrachloro-meta-phthalo-dinitrile;Tetrachloro-m-phthalodinitrile;Tpn (pesticide);tpn(pesticide);Tripart faber;Tripart ultrafaber;Tuffcide;Vanox
CAS:1897-45-6
MF:C8Cl4N2
MW:265.91
EINECS:217-588-1
Product Categories:Agro-Products;Aromatics;Mutagenesis Research Chemicals;Alpha sort;AromaticsPesticides&Metabolites;C;CAlphabetic;CHMethod Specific;Endocrine Disruptors (Draft);EPA;Fungicides;Pesticides;FUNGICIDE;Organics
Mol File:1897-45-6.mol
Chlorothalonil Structure
Chlorothalonil Chemical Properties
Melting point 250-251°
Boiling point bp760 350°
density d425 1.7
vapor pressure 7.6 x 10-5 Pa (25 °C)
Fp 2 °C
storage temp. 0-6°C
solubility 180mg/L in organic solvents at 20 ℃
Water Solubility 0.6-1.2 mg l-1 (25 °C)
form Powder
color White
Odorodorless in pure form
Merck 14,2166
BRN 1978326
Exposure limitsAn experimental carcinogen.
Stability:Light Sensitive
InChIKeyCRQQGFGUEAVUIL-UHFFFAOYSA-N
LogP2.94 at 25℃
CAS DataBase Reference1897-45-6(CAS DataBase Reference)
IARC2B (Vol. Sup 7, 73) 1999
NIST Chemistry ReferenceTetrachloroisophthalonitrile(1897-45-6)
EPA Substance Registry SystemChlorothalonil (1897-45-6)
Safety Information
Hazard Codes T+;N,N,T+,Xn,F
Risk Statements 26-37-40-41-43-50/53-36-20/21/22-11
Safety Statements 28-36/37/39-45-60-61-36/37-26-16
RIDADR 3276
WGK Germany 3
RTECS NT2600000
HazardClass 6.1(a)
PackingGroup I
HS Code 29269090
Hazardous Substances Data1897-45-6(Hazardous Substances Data)
ToxicityLD50 orally in rats: >10.0 g/kg (Turner)
MSDS Information
Chlorothalonil Usage And Synthesis
DescriptionChlorothalonil is a broad-spectrum organic fungicide mainly used to control fungi that threatens a number of agricultural crops, vegetables, trees, fruits, turf and paints, etc. It can also serves as a wood protectant, pesticide, acaricide, which is effective to kill mildew, bacteria, algae, and insects. Besides, it can commercially act as a preservative additive in several paints, resins, emulsions, coatings and can be used on commercial grasses such as golf courses and lawns.
Chlorothalonil was first registered by the EPA in 1966. It is environmentally persistent and binds strongly with soil, whose expected half-life in aerobic soils is one to three months. Chlorothalonil functions by reducing the intracellular glutathione molecules of fungal to alternate its forms which affects the essential enzymatic reactions of fungal, ultimately leading to cell death.
usesChlorothalonil is a fungicide with a broad spectrum of activity used mainly in agriculture but also on turf, lawns and ornamental plants. It protects plants against a variety of fungal infections such as rusts, downy mildew, leaf spot, scabs, blossom blight and black pod. Crops protected include pome fruit, stone fruit, citrus, currants, cranberries, strawberries, bananas, vines, hops, tomatoes, green vegetables, tobacco, coffee, tea, soya bean, groundnuts, potatoes, onions, cereals and sugar beet. In addition, it is used in wood preservatives, fish net coatings and anti-fouling paints.
Referenceshttp://www.toxipedia.org/display/toxipedia/Chlorothalonil
http://pmep.cce.cornell.edu/profiles/extoxnet/carbaryl-dicrotophos/chlorothalonil-ext.html
https://en.wikipedia.org/wiki/Chlorothalonil

DescriptionChlorothalonil is a pesticide fungicide commonly used in the cultivation of ornamental plants and flowers, rice, and onions. In banana plantations it is used in fumigations by airplanes. It can be used as a preservative of paints and of woods. Chlorothalonil can induce contact urticaria, irritant and allergic contact dermatitis, erythema dychromicum perstans or folliculitis mainly in agricultural workers, in those in wood-related professions or in hortieulturists.
Chemical PropertiesChlorothalonil is a combustible, white, odorless, crystalline solid
UsesChlorothalonil is a non-systemic foliar fungicide with protective activity. It is used to control a broad spectrum of fungal diseases in fruit (pome, stone, citrus, etc.), berries, vegetables, cucurbits, root crops, soyabeans, ornamentals and turf.
UsesChlorothalonil is a polychlorinated aromatic broad spectrum non-systematic fungicide. Chlorothalonil is used heavily in agriculture field on crops such as peanuts, potatoes and tomatoes. Chlorothaloni l is a probable human carcinogen (Group B2) and is highly toxic to fish and aquatic invertabrates.
DefinitionChEBI: A dinitrile that is benzene-1,3-dicarbonitrile substituted by four chloro groups. A non-systemic fungicide first introduced in the 1960s, it is used to control a range of diseases in a wide variety of crops.
General DescriptionColorless crystals or granules or light gray powder. Melting point 250-251°C. No odor when pure; technical grade has a slightly pungent odor. A fungicide formulated as water-dispersible granules, wettable powder, or dust.
Air & Water ReactionsInsoluble in water.
Reactivity ProfileChlorothalonil is stable in neutral or acidic aqueous media. May react violently with strong oxidizing acids [Farm Chemicals Handbook]. Incompatible with other oxidizing agents such as peroxides and epoxides. Breaks down slowly in basic aqueous media (half-life 38.1 days at pH 9. [Farm Chemicals Handbook].
Health HazardChlorothalonil is an irritant to the skin and eyes and has been reported to produce allergic contact dermatitis in exposed workers.
Fire HazardLiterature sources indicate that Chlorothalonil is nonflammable.
Flammability and ExplosibilityNotclassified
Agricultural UsesFungicide: Chlorothalonil is a broad-spectrum fungicide. It is used on vegetables, peanuts, potatoes, small fruits, trees, turf, roses, ornamentals, and other crops. In California, the top crops are tomatoes, onions, celery, and landscaping. It targets fungal blights, needlecasts, and cankers on conifer trees. This is the second most used fungicide in the U.S. It can be found in formulations with many other pesticides
Trade nameATLAS CROPGARD®; BANOL C®; BB CHLOROTHALONIL®; BOMmHgDIER®; BRAVO®; BRAVO® 6 F; BRAVO® 500; BRAVO® 6 F; BRAVO ULTREX®; BRAVO-W-75®; CHILTERN OLE®; CONTACT® 75; DAC® 2787; DACONIL®; DACONIL® 2787 FUNGICIDE; DACONIL® 2787 W; DACONIL® F; DACONIL® M; DACONIL® TURF; DACOSOIL®; DIVA FUNGICIDE®[C]; ECHO®; EXOTHERM®; EXOTHERM TERMIL®; FORTURF®; FUNGINIL®; IMPACT EXCEL®; JUPITAL®; NUOCIDE®; OLE®; PILLARICH®; POWER CHLOROTHALONIL® 50; REPULSE®; RIDOMIL GOLD/BRAVO®; SICLOR®; SIPCAM® UK ROVER 5000; SWEEP®; TER-MIL®; TPN®; TPN (PESTICIDE)®; TRIPART FABER®; TRIPART ULTRAFABER®; TUFFCIDE®
Contact allergensChlorothalonil is a fungicide widely used in the cultivation of ornamental plants and flowers, rice, and onions. In banana plantations it is used in fumigations by airplanes. It can be used as a preservative of paints and woods. It can induce contact urticaria, irritant and allergic contact dermatitis, erythema dyschromicum perstans, or folliculitis mainly in agricultural workers, wood-related professions, or in horticulturists.
PharmacologyMechanism of action of this fungicide may be attributed to inhibition of physiological activities of fungal cell constituents by binding reaction. The reaction was observed in buffer solution to substitute hydroxyethylthio radical(s) of 2-mercaptoethanol for chlorine radical(s) on the benzene ring of the fungicide molecule preferably at 4-position (i.e., also 6-) followed by other positions (5). Similar reactions in fungal cells were observed between the fungicide and glutathione and high molecular weight cell constituents having a sulfhydryl group (5,6). The fungicide inhibits activities of thiol-dependent enzymes such as alcohol dehydrogenase, gyceraldehyde-3-phosphate dehydrogenase, and malate dehydrogenase (5,6). Preliminary addition of glutathione or dithiothreitol protects the thiol enzymes from inhibition but later addition does not reverse the enzyme inhibition. Chymotrypsin, a non-thiol enzyme, was not inhibited by this fungicide. Binding of the fungicide to the sulfhydryl group of cell constituents appears to be the primary mode of its action.
Safety ProfileSuspected carcinogen with experimental carcinogenic data. Moderately toxic by skin contact and intraperitoneal routes. Mildly toxic by ingestion. Mutation data reported. When heated to decomposition it emits very toxic fumes of Cl-, NOx, and CN-. See also NITRILES.
Potential ExposureChlorothalonil is a broad spectrum fungicide; used as fungicide in coatings; caulk, wood preservative, and antifouling systems. Therefore, people involved in its manufacture, formulation, and application can be exposed.
CarcinogenicityChlorothalonil was not mutagenic in a variety of assays, nor did it bind to DNA.3 The compound does not appear to have genotoxic potential and probably exerts its carcinogenic action in rodents via a nongenotoxic mechanism. 3 Rodent models may be a poor predictor of carcinogensis in humans because of species differences in metabolic pathways leading to carcinogenesis in the kidney and the lack of a comparable organ (forestomach) in humans.
The IARC has determined that there is sufficient evidence for carcinogenicity of chlorothalonil in experimental animals and inadequate evidence in humans.
Environmental FateBiological. From the first-order biotic and abiotic rate constants of chlorothalonil in estuarine water and sediment/water systems, the estimated biodegradation half-lives were 8.1–10 and 1.8–5 days, respectively (Walker et al., 1988).
Soil. Metabolites identified in soil were 1,3-dicyano-4-hydroxy-2,5,6-trichlorobenzene, 1,3-dicarbamoyl-2,4,5,6-tetrachlorobenzene and 1-carbamoyl-3-cyano-4-hydroxy-2,5,6- trichlorobenzene (Rouchaud et al., 1988). The half-life was reported as 4.
Groundwater. According to the U.S. EPA (1986) chlorothalonil has a high potential to leach to groundwater
Plant. Degrades in plants to 4-hydroxy-2,5,6-trichloroisophthalonitrile (Hartley and Kidd, 1987), 1,3-dicyano-4-hydroxy-2,5,6-trichlorobenzene and 1,3-dicarbamoyl-2,4,5,6- tetrachlorobenzene (Rouchaud et al., 1988). No evidence of degradation products were reported in apple foliage 15 days after application. The half-life of chlorothalonil was 4.1 days (Gilbert, 1976)


Metabolic pathwayBy in vitro incubation of 14C-chlorothalonil (CTL) with rat stomach, duodenum, and cecum contents, with dog stomach, duodenum, and colon contents, and with human feces and stomach contents, transformation of CTL mostly occurs in rat cecum contents, dog colon contents, and human feces, in which unchanged CTL accounts for 46.7, 29.7, and 22.6% of applied radioactivity, respectively. In those incubations, the identified metabolites are 2,5,6-trichloro-4- methylthioisophthalonitrile, 2,5,6-trichloro-4- thioisophthalonitrile, 3-thia-1-cyano-2,5,6- trichloroisoindolinone, 2,5,6-trichloro-4- hydroxyisophthalonitrile, and 2,5,6- trichloroisophthalonitrile. In rats, CTL is transformed to 4,6-bis(N-acetylcystein-S-yl)-2,5- dichloroisophthalonitrile.
The photolysis of CTL solutions in alcohols (ethanol and methanol separately) with exposure to UV irradiation yields 4,5,7-trichloro-6-cyano-3- methylbenzo-g -lactone and dichlorobenzo-bis-g -lactone derivatives as major degradation products in ethanol. In methanol, 4,5,7-trichloro-6-cyanobenzo-g -lactone is the only photoproduct detected.
MetabolismDegradation pathways of chlorothalonil in upland and paddy soils (7) and by soil bacteria (8) were studied, and most initial products were identified to be the results of chlorine substitution reactions, by hydrogen (i.e., dechlorination), by hydroxyl, and by methylthio groups. These reactions took place first at the 4-position of the ring followed by reactions at other positions as in the reaction with thiol compounds. Paddy soil degraded the fungicide faster than did upland soil. Chlorine substitution reaction at 4-position of the fungicide molecule was also reported in benzene solution under sunlight, and the phenyl-substituted product was identified (9). Similar photolysis was observed in other aromatic hydrocarbon solutions but not in acetone, hexane, and ether solutions.
ShippingUN3276 Nitriles, liquid, toxic, n.o.s., Hazard Class: 6.1; Labels: 6.1-Poisonous materials, Technical Name Required, Potential Inhalation Hazard (Special Provision 5). UN2588 Pesticides, solid, toxic, Hazard Class: 6.1; Labels: 6.1-Poisonous materials, Technical Name Required
DegradationChlorothalonil is stable to aqueous hydrolysis at pH values above 7. It is hydrolysed slowly at pH 9 via dechlorination to yield 4-hydroxy-2,5,6- trichloroisothalonitrile (2) and oxidation/hydration of one of the nitrile groups to yield 3-cyano-2,4,5,6-tetrachlorobenzamide (3) (Szalkowski and Stallard, 1977).
Toxicity evaluationChlorothalonil’s production and use as a broad-spectrum, nonsystemic, protectant pesticide results in its direct release to the environment. Its uses as a wood protectant, antimold and antimildew agent, bactericide, microbiocide, algaecide, insecticide, and acaricide are additional routes of release. If released to air, chlorothalonil will exist in both the vapor and particulate phases in the ambient atmosphere. Vapor-phase chlorothalonil will be degraded slowly in the atmosphere by reaction with photochemically produced hydroxyl radicals (reaction half-life ~7 years). Direct photolysis may also occur. Chlorothalonil is removed from the atmosphere by wet and dry deposition. If released to soil, chlorothalonil is expected to have lowmobility or be immobile, based on Koc values in the range of 900–7000 measured in four soils. Volatilization from moist or dry soil surfaces is not expected to be important based on a Henry’s Law constant of 2.5×10-7 atm-cummol-1. Aerobic biodegradation half-lives of chlorothalonil in four different soils ranged from 10 to 40 days. If released into water, chlorothalonil is expected to adsorb to suspended solids and sediment in the water column.
IncompatibilitiesContact with strong oxidizers may cause a fire and explosion hazard. Thermal decomposition may include fumes of hydrogen cyanide. Nitriles may polymerize in the presence of metals and some metal compounds. They are incompatible with acids; mixing nitriles with strong oxidizing acids can lead to extremely violent reactions. Nitriles are generally incompatible with other oxidizing agents such as peroxides and epoxides. The combination of bases and nitriles can produce hydrogen cyanide. Nitriles are hydrolyzed in both aqueous acid and base to give carboxylic acids (or salts of carboxylic acids). These reactions generate heat. Peroxides convert nitriles to amides. Nitriles can react vigorously with reducing agents. Acetonitrile and propionitrile are soluble in water, but nitriles higher than propionitrile have low aqueous solubility. They are also insoluble in aqueous acids.
Waste DisposalIncineration in a unit operating @ 850C equipped with off-gas scrubbing equipment.
Chlorothalonil Preparation Products And Raw materials
Raw materialsHydrochloric acid-->Ammonia-->Chlorine-->CARBON DIOXIDE-->Activated carbon-->Benzonitrile-->m-Xylene-->Bifenthrin-->1,3-Dicyanobenzene
Preparation Products2,4,5-Trifluorobenzoic acid
Chlorothalonil+Mancozeb,W.P. CHLOROTHALONIL SOLUTION 100UG/ML IN ACETONITRILE 1ML CHLOROTHALONIL SOLUTION Chlorothalonil+Thiram,W.P. CHLOROTHALONIL SOLUTION 100UG/ML IN T-BUTYLMETHYL ETHER 5X1ML 2,4,5,6-Tetrafluoroisophthalonitrile 2,4,5,6-TETRACHLORO-M-XYLENE Tetrachlorophthalic acid CHLOROTHALONIL [RING-14C(U)] Chlorothalonil+Thiram+Ziram,W.P. CHLOROTHALONIL SOLUTION 100UG/ML IN T-BUTYLMETHYL ETHER 5ML 2,3,6-Trichlorotoluene Chlorothalonil+Pyrimethanil,W.P. Chlorothalonil+Diniconazole,suspensoid (40%) 2,3,4-Trichlorotoluene Carbendazim+Chlorothalonil,W.P. 2-Chloro-1,3-dimethylbenzene CHLOROTHALONIL SOLUTION 100UG/ML IN T-BUTYLMETHYL ETHER 1ML
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