106-93-4 Usage
Description
1,2-Dibromoethane, also known as Ethylene Dibromide (EDB), is a colorless, non-flammable liquid with a sweet, chloroform-like odor. It is a heavy, colorless liquid with a mild sweet odor and is soluble in various organic solvents, slightly soluble in water, and reacts with lead residues to generate volatile lead bromides. It is a bromohydrocarbon and a bromoalkane, produced by marine algae and has roles as a fumigant, a carcinogenic agent, a marine metabolite, an algal metabolite, a mouse metabolite, and a mutagen.
Uses
Used in Automotive Industry:
1,2-Dibromoethane is used as a lead scavenger in antiknock mixtures added to gasolines. It transforms the combustion products of tetraalkyl lead additives to forms that are more likely to be vaporized from engine surfaces.
Used in Agricultural Industry:
1,2-Dibromoethane is used as a fumigant for grains, a pesticide, and an ingredient of soil, vegetable, fruit, and grain fumigant formulations. It is also used as a nematicide, although it is not approved for use in EU countries and not registered for use in the U.S.
Used in Chemical Synthesis:
1,2-Dibromoethane is used as a solvent and in the manufacture of other chemicals, such as dyes and waxes.
Used in Wood Treatment:
1,2-Dibromoethane is used as a fumigant for the treatment of logs for termites and beetles.
Used in Beekeeping:
1,2-Dibromoethane is used for the control of moths and beehives.
Preparation
1,2-Dibromoethane is manufactured via uncatalyzed, liquid-phase bromination of ethylene. Gaseous ethylene is brought into contact with bromine by various methods, allowing for dissipation of the heat of the reaction.
Air & Water Reactions
Slightly soluble in water. May react slowly with moisture.
Reactivity Profile
1,2-Dibromoethane slowly decomposes in the presence of light and heat. Turns brown upon exposure to light. Corrosive to iron and other metals. May decompose upon contact with alkalis. Incompatible with oxidizing agents. Reacts with sodium, potassium, calcium, powdered aluminum, zinc, magnesium and liquid ammonia. May attack some plastics, rubber and coatings. May poison platinum catalysts [Hawley]. Reacts as an alkylating agent .
Hazard
Probable carcinogen. Toxic by inhalation,
ingestion, and skin absorption; strong irritant to
eyes and skin.
Health Hazard
Local inflammation, blisters and ulcers on skin; irritation in lungs and organic injury to liver and kidneys; may be absorbed through skin.
Health Hazard
1,2-Dibromoethane is toxic by inhalation,ingestion, or skin contact. The acute toxicsymptoms are depression of the central ner vous system, irritation and congestion oflungs, hepatitis, and renal damage. Chronicexposure can produce conjunctivitis, bron chial irritation, headache, depression, lossof appetite, and loss of weight. Recoveryoccurs after cessation of exposure. Prolongedor repeated exposures to high concentrationscan be fatal to animals and humans. Lethalconcentration for a 2-hour exposure period is400 ppm in rats.1,2-Dibromoethane is moderate to highlytoxic by ingestion. Its toxicity is far greaterthan that of 1,2-dichloroethane. An oralintake of 5 to 10 mL of the liquid can be fatalto humans. Death occurs from necrosis of theliver and kidney damage. The oral LD50 val ues varied between 50 and 125 mg/kg fordifferent species of laboratory animals.Vapors are irritant to the eyes. Contactwith the liquid can damage vision. Skincontact may produce severe irritation andblistering.Mutagenic tests were positive, while thehistidine reversion–Ames test gave incon clusive results (NIOSH 1986). 1,2-Dibromo ethane is carcinogenic to animals and issuspected to cause cancer in humans. Inhala tion of this compound produced tumors inthe lungs and nose in mice and rats. Oraladministration caused cancers in the liver andgastrointestinal tract.
Flammability and Explosibility
Ethylene dibromide is a noncombustible substance (NFPA rating = 0).
Trade name
AADIBROOM?; EDB-85; FUMO-GAS?;
ISCOBROME D?; KOPFUME?; NEFIS?; NEPHIS?;
SOILFUME?; UNIFUME?
Safety Profile
Confirmed carcinogen
with experimental carcinogenic,
neoplastigenic, and teratogenic data. Human
poison by ingestion. Experimental poison by
ingestion, sktn contact, intraperitoneal, and
possibly other routes. Moderately toxic by
inhalation and rectal routes. Human
systemic effects by ingestion: hypermothty,
barrhea, nausea or vomiting, decreased
urine volume or anuria. Experimental
reproductive effects. Human mutation data
reported. A severe skin and eye irritant.
Implicated in worker sterdity. When heated
to decomposition it emits toxic fumes of Br-. See also ETHYLENE DICHLORIDE
and BROMIDES.
Potential Exposure
Ethylene dibromide is used as a chemical intermediate; as a fumigant for ground pest control; as
a constituent of ethyl gasoline (anti-knock agent). It is also
used in fire extinguishers, gauge fluids, and waterproofing
preparations; and it is used as a solvent for celluloid, fats,
oils, and waxes. Pesticide not in use; TRI and/or IUR indicates importers or manufacturers are unlikely
Carcinogenicity
1,2-Dibromoethane is reasonably anticipated to be a human carcinogen based on sufficient evidence of carcinogenicity from studies in experimental animals.
Cancer Studies in Experimental Animals
Metabolic pathway
The bacterial strain GP1 can utilize 1,2-dibromoethane
as a sole carbon and energy source. The first step in
1,2-dibromoethane is catalyzed by a hydrolytic
haloalkane dehalogenase and the resulting 2-
bromoethanol is rapidly converted to ethylene oxide,
preventing the accumulation of 2-bromoethanol and 2-
bromoacetaldehyde. However, the further metabolic
pathway(s) is unclear.
storage
work with EDB should be conducted in a fume hood to prevent exposure by inhalation, and appropriate impermeable gloves and safety goggles should be worn to prevent skin contact. Gloves and protective clothing should be changed immediately if EDB contamination occurs. Since EDB can penetrate neoprene and other plastics, protective apparel made of these materials does not provide adequate protection from contact with EDB.
Shipping
UN1605/154 Ethylene dibromide, Hazard Class:
6.1; Labels: 6.1-Poison Inhalation Hazard, Inhalation
Hazard Zone B
Purification Methods
Wash the dibromide with conc HCl or H2SO4, then water, aqueous NaHCO3 or Na2CO3, more water, and dry it with CaCl2. Fractionally distil it. Alternatively, keep in daylight with excess bromine for 2hours, then extract with aqueous Na2SO3, wash with water, dry with CaCl2, filter and distil. It can also be purified by fractional crystallisation by partial freezing. Store it in the dark. [Beilstein 1 H 90, 1 I 28, 1 II 61, 1 III 182, 1 IV 158.]
Incompatibilities
Reacts vigorously with chemically
active metals; liquid ammonia, strong bases; strong
oxidizers; causing fire and explosion hazard. Light, heat,
and moisture can cause slow decomposition, forming
hydrogen bromide. Attacks fats, rubber, some plastics and
coatings.
Waste Disposal
Controlled incineration with
adequate scrubbing and ash disposal facilities
Check Digit Verification of cas no
The CAS Registry Mumber 106-93-4 includes 6 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 3 digits, 1,0 and 6 respectively; the second part has 2 digits, 9 and 3 respectively.
Calculate Digit Verification of CAS Registry Number 106-93:
(5*1)+(4*0)+(3*6)+(2*9)+(1*3)=44
44 % 10 = 4
So 106-93-4 is a valid CAS Registry Number.
InChI:InChI=1/C2H4Br2/c3-1-2-4/h1-2H2
106-93-4Relevant articles and documents
Absolute Rate Constants for Bromine Abstraction from N-Bromoimides and Br2 by Alkyl Radicals
Tanko, James M.,Skell, Philip S.,Seshadri, Sri
, p. 3221 - 3225 (1988)
Imidyl radicals react with cyclopropanes solely via hydrogen abstraction.In the case of methylcyclopropane, the major product (cyclopropylcarbinyl bromide) is derived from abstraction of hydrogen from the methyl group.The resultant cyclopropylcarbinyl radical is partioned between two pathways: (1) abstraction of Br from N-bromoimide and (2) rearrangement to the allylcarbinyl radical (eventually yielding 4-bromo-1-butene).Since the absolute rate of the rearrangement is known, an absolute rate constant for the abstraction of Br from N-bromoimides by alkyl radicals can be derived (CH2Cl2 solvent, 15 deg C), k ca. (1.3-1.6)1xE10 M-1s-1.Reactions carried out in the presence of Br2 provide a third pathway for scavenging of the cyclopropylcarbinyl radical, providing kBr2=2.2x1E10 M-1s-1.Thus, trapping of primary R. by either N-bromoimides or Br2 occurs at rates that are diffusion-controlled.
Ionic Bromination of Ethane and Other Alkanes (Cycloalkanes) with Bromine Catalyzed by the Polyhalomethane*2AlBr3 Aprotic Organic Superacids under Mild Conditions
Akhrem, Irena S.,Orlinkov, Alexander V.,Afanas'eva, Lyudmila V.,Mysov, Evgenii I.,Vol'pin, Mark E.
, p. 9365 - 9368 (1995)
The polyhalomethane*2AlBr3 aprotic organic superacids were shown to effectively catalyze low-temperature ionic bromination of (cyclo)alkanes.Ethane readily reacts with Br2 at 55-65 deg C, affording mainly 1,2-dibromoethane.Propane, butane, and C5-C6 cycloalkanes react at -40 - -20 deg C, resulting in monobromides with high yields and good selectivity.
Photolysis of 3-Bromo-3-methyldiazirine
Crespo, Maria T.,Figuera, Juan M.,Rodriguez, Juan C.,Utrilla, Roberto Martinez
, p. 5790 - 5796 (1984)
The photolysis at 354 nm of 3-bromo-3-methyldiazirine in gas phase has been studied.After a careful search of the various possibilities we have found that all available evidence points toward the intermediary formation of hot vinyl bromide, presumably via isomerization of the corresponding carbene.Its unimolecular decomposition can take place by two different paths: one is the molecular detachment of HBr and the other the radical scission of the C-Br bond.This last way of radical formation is responsible for the apparently confusing experimental data.According to our result the activation energy for the radical decomposition is closer to that of the molecular detachment than previously thought.
Etzler,Rollefson
, (1939)
Reactivity of Alkaneselenyl Bromide: Conversion of Alcohols into the Corresponding Alkyl Bromides with Dialkylselenium Dibromide
Akabori, Sadatoshi,Takanohashi, Yoshinori
, p. 3482 - 3484 (1991)
The reaction of alcohols with dialkylselenium dibromide gave the corresponding bromides in moderate to high yields.Alkaneselenyl bromide, produced by the thermal decomposition from dialkylselenium dibromide, acts as a brominating agent.The reaction of alcohol with dialkylselenium dichloride afforded the corresponding chlorides, although the yields were realtively low compared with those of the bromide.
Oxidative bromination of alkenes mediated with nitrite in ionic liquids
Kuznetsova, Lidia I.,Kuznetsova, Nina I.,Zudin, Vladimir N.,Utkin, Viktor A.,Trebushat, Dmitry V.,Fedotov, Martin A.,Larina, Tatyana V.
, p. 1499 - 1506,8 (2014)
The oxidative bromination of C2-C8 alkenes with HBr-NaNO2-O2 in solutions of BMImBr, HMImBr or BMImBF 4 containing 16-28 wt% H2O was studied using volumetric method, GC-MS analysis, 14N NMR and UV-VIS spectroscopy. The optimal conditions to conduct the reaction at high selectivity for 1,2-dibromoalkanes in BMImBr were determined. The composition of ionic liquid affects the catalytic performance. Although in BMImBF4 the reaction runs with equal rate as in bromide ionic liquid, the fraction of bromohydrin in the reaction products increases to 20 %. Generated from NaNO2, NOx operated as a catalyst in the oxidation of Br- and was oxidized to catalytically inert NO3 - anions when complete conversion of HBr was attained. Graphical Abstract: Oxidative bromination of alkenes [Figure not available: see fulltext.]
Formation of acridones by ethylene extrusion in the reaction of arynes with β-lactams and dihydroquinolinones
Fang, Yuesi,Rogness, Donald C.,Larock, Richard C.,Shi, Feng
scheme or table, p. 6262 - 6270 (2012/09/22)
N-Unsubstituted β-lactams react with a molecule of aryne by insertion into the amide bond to form a 2,3-dihydroquinolin-4-one, which subsequently reacts with another molecule of aryne to form an acridone by extrusion of a molecule of ethylene. 2,3-Dihydroquinolin-4-ones react under the same reaction conditions to afford identical results. This is the first example of ethylene extrusion in aryne chemistry.