110-80-5 Usage
Chemical Description
2-ethoxyethanol is a solvent used in organic synthesis.
Description
2-Ethoxyethanol, also known as Ethyl Cellosolve or Cellosolve, is a stable, colorless, flammable liquid that belongs to the larger group of glycol ether solvents. It is a synthetically produced compound with chemical properties of both alcohols and ethers, possessing hydrophilic and lipophilic characteristics. This glycol ether is made by reacting anhydrous alcohols with ethylene oxide and is less volatile than other solvents, which enhances production characteristics. It is a colorless, viscous liquid with a sweetish odor and is miscible in polar and nonpolar solutions.
Uses
Used in Paints and Surface Coatings Industry:
2-Ethoxyethanol is used as a solvent for paints and surface coatings, stains, lacquers, inks, and dyes due to its miscibility in polar and nonpolar solutions.
Used in Industrial Deicing:
2-Ethoxyethanol is used as a deicing agent in industrial applications.
Used in Hydraulic Fluids:
2-Ethoxyethanol is used as a component in hydraulic fluids.
Used in Cleaning Agents:
2-Ethoxyethanol is used as a cleaning agent in various industries.
Used in Varnish Removers, Lacquers, and Printing Inks:
2-Ethoxyethanol is used as a solvent in varnish removers, lacquers, and for printing inks, duplicating fluids, and epoxy.
Used in Water-Based Coatings, Vinyl and Acrylic Paints and Varnishes:
2-Ethoxyethanol is used as a coupling agent for water-based coatings and as a solvent for vinyl and acrylic paints and varnishes.
Used as an Emulsion Stabilizer:
2-Ethoxyethanol is used as an emulsion stabilizer in various applications.
Used as an Antiobesity Agent (Pancreatic Lipase Inhibitor):
2-Ethoxyethanol has been identified as a potential antiobesity agent, functioning as a pancreatic lipase inhibitor.
However, it is important to note that 2-Ethoxyethanol was once used in cosmetic products but is no longer used due to toxicity associated with dermal absorption. Global production has been on the decline in recent years based on demonstrated toxicity through oral, dermal, and inhalation routes of exposure. The use of ethylene glycol ethers has largely been replaced by relatively safer substitutes, primarily propylene glycol ethers. Nonetheless, its use as a solvent and chemical process intermediate poses potential for release into the environment.
Air & Water Reactions
Flammable. Water soluble.
Reactivity Profile
ETHYLENE GLYCOL MONOMETHYL ETHER may react with oxidizing materials, i.e. hydrogen peroxide, to form peroxides. 2-Ethoxyethanol dissolves many oils, resins and waxes.
Hazard
Toxic by skin absorption. Moderate fire
risk.
Health Hazard
Some eye irritation. Inhalation of vapors causes irritation of nose.
Health Hazard
EGEE is a teratogen and at high concentration a toxic substance. The target organs arethe lungs, kidney, liver, and spleen. Animalexperiments indicated that inhalation of itsvapors at 2000 ppm for several hours couldproduce toxic effect. Death resulted from kid ney injury when the test species were sub jected to a 24-hour exposure. It producedkidney injury, hematuria, and microscopiclesions of both the liver and kidney. EGEEmay be absorbed through the skin. Wheninserted into the eyes, it produced corneal irritation. The recovery occurred within 24 hoursInvestigating the subchronic inhalationtoxicology of EGEE in the rat and rabbit,Barbee et al. (1984) reported no biologicalsignificant effect of this compound in theseanimals at an exposure level of 400 and100 ppm, respectively. Chronic treatment ofrats with EGEE at 0.5–1.0 g/kg in an oraldose caused enlargement of adrenal gland inmale rats and affected the development ofspontaneous lesions of the spleen (males andfemales), pituitary (males and females), andLD50 value(rats):3000 mg/kg(NIOSH1986)testis (males) (Melnick 1984).LC50 value (mice): 1820 ppm/7 hr (NIOSH 1986) In humans there is no report of any severe poisoning case. The toxic effect from inhaling its vapors at 1000 ppm may be less than noticeable. EGEE is less toxic than EGME. Whenadministeredorallyto youngmale rats, EGEE produced testicular atrophy similar to that of EGME (Nagano et al. 1984). However, a fivefold dose, 250–1000 mg/kg/day, was required to elicit equivalent severity (Foster et al. 1984)Reproductive toxicity of EGEE has been investigated extensively (Lamb et al. 1984; Hardin et al. 1984; Oudiz et al. 1984). Testicular atrophy, decline in sperm count, and increased abnormal sperm were observed in treated male rats, but no specific anomalies were noted in the females. Wier et al. (1987) investigated postnatal growth and survival. EGEE produced embryo lethality and malformations and decreased fetal weight. Prenatal exposure to EGEE produced kinked tails in pups. Ethanol caused potentiation of reproductive toxicity of EGEE (Nelson et al. 1984).
Fire Hazard
Special Hazards of Combustion Products: Toxic gases, such as carbon monoxide, may be produced in fire.
Chemical Reactivity
Reactivity with Water No reaction; Reactivity with Common Materials: No reaction; Stability During Transport: Stable; Neutralizing Agents for Acids and Caustics: Not pertinent; Polymerization: Not pertinent; Inhibitor of Polymerization: Not pertinent.
Safety Profile
Moderately toxic by
ingestion, skin contact, intravenous, and
intraperitoneal routes. Mildly toxic by
inhalation and subcutaneous routes. An
experimental teratogen. Other experimental
reproductive effects. A mild eye and skin
irritant. Combustible when exposed to heat
or flame; can react with oxidzing materials.
Moderate explosion hazard in the form of
vapor when exposed to heat or flame.
Mxture with hydrogen peroxide +
polyacrylamide gel + toluene is explosive
when dry. To fight fire, use alcohol foam,
dry chemical. See also GLYCOL ETHERS.
Potential Exposure
This material is used as a solvent for
nitrocellulose and alkyd resins in lacquers; as a solvent for
printing inks; in dyeing leathers and textiles; in the formulation of cleaners and varnish removers; as an anti-icing
additive in brake fluids and auto and aviation fuels.
Environmental fate
Biological. Bridié et al. (1979) reported BOD and COD values of 1.03 and 1.92 g/g using
filtered effluent from a biological sanitary waste treatment plant. These values were determined
using a standard dilution method at 20 °C for a period of 5 d. When a sewage seed was used in a
separate screening test, a BOD value of 1.27 g/g was obtained. Similarly, Heukelekian and Rand
(1955) reported a 5-d BOD value of 1.42 g/g which is 72.4% of the ThOD value of 1.96 g/g.
Photolytic. Grosjean (1997) reported a rate constant of 1.87 x 10-11 cm3/molecule?sec at 298 K
for the reaction of 2-ethoxyethanol and OH radicals in the atmosphere. Based on an atmospheric
OH radical concentration of 1.0 x 106 molecule/cm3, the reported half-life of methanol is 0.35 d
(Grosjean, 1997). Stemmler et al. (1996) reported a rate constant of 1.66 x 10-11 cm3/molecule?sec
for the OH radical-initiated oxidation of 2-ethoxyethanol in synthetic air at 297 K and 750 mmHg.
Major reaction products identified by GC/MS (with their yields) were ethyl formate, 34%;
ethylene glycol monoformate, 36%; ethylene glycol monoacetate, 7.8%; and ethoxyacetaldehyde,
24%.
Chemical/Physical. 2-Ethoxyethanol will not hydrolyze (Kollig, 1993).
At an influent concentration of 1,024 mg/L, treatment with GAC resulted in an effluent
concentration of 886 mg/L. The adsorbability of the carbon used was 28 mg/g carbon (Guisti et
al., 1974).
Shipping
UN1171 Ethylene glycol monoethyl ether,
Hazard Class: 3; Labels: 3-Flammable liquid.
Purification Methods
Dry it with CaSO4 or K2CO3, filter and fractionally distil it. Peroxides can be removed by refluxing with anhydrous SnCl2 or by filtration under slight pressure through a column of activated alumina. [Beilstein 1 IV 2377.]
Toxicity evaluation
The toxicity associated with 2-ethoxyethanol is likely caused
more by the primary metabolite, ethoxyacetic acid, than by the
parent compound. The metabolites have a longer half-life
implying a higher accumulation following repeated exposures.
Both in vitro and in vivo studies have shown toxic effects from
administration of the metabolites that were not seen at higher
doses of the parent. Developmental and male reproductive
toxicity has been widely documented for several compounds in
the glycol ether family, and potency is associated with the
length of the hydrocarbon chain: the shorter the chain, the
more potent the developmental and reproductive effects.
Despite the vast collection of toxicity studies conducted internationally,
the exact mechanism of developmental and reproductive
toxicity is not well understood. A potential mechanism
for the male reproductive toxicity is direct action on Sertoli
and/or germ cells by ethoxyacetic acid. The testes have relatively
high levels of cytochrome P450 and are an active site of
metabolism. Investigators have found that ethoxyacetic acid
can cause degeneration of spermatocytes in vitro, and damage
to spermatocytes seen in vivo can be suppressed when metabolism
of 2-ethoxyethanol is inhibited.
Incompatibilities
May form explosive mixture with air.
Strong oxidizers may cause fire and explosions. Attacks
some plastics, rubber and coatings. Able to form peroxides. Incompatible with strong acids; aluminum and its
alloys
Waste Disposal
Dissolve or mix the material
with a combustible solvent and burn in a chemical incinerator equipped with an afterburner and scrubber. All federal,
state, and local environmental regulations must be
observed. Consult with environmental regulatory agencies
for guidance on acceptable disposal practices. Generators of
waste containing this contaminant (≧100 kg/mo) must conform with EPA regulations governing storage, transportation,
treatment, and waste disposal
Check Digit Verification of cas no
The CAS Registry Mumber 110-80-5 includes 6 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 3 digits, 1,1 and 0 respectively; the second part has 2 digits, 8 and 0 respectively.
Calculate Digit Verification of CAS Registry Number 110-80:
(5*1)+(4*1)+(3*0)+(2*8)+(1*0)=25
25 % 10 = 5
So 110-80-5 is a valid CAS Registry Number.
InChI:InChI=1/C4H10O.C2H6O2/c1-3-5-4-2;3-1-2-4/h3-4H2,1-2H3;3-4H,1-2H2
110-80-5Relevant articles and documents
Davis,Brown
, p. 2166 (1971)
-
Dolgopolow,Melnikow,Nametkin
, p. 487,489 (1948)
-
Selective synthesis of dimethoxyethane via directly catalytic etherification of crude ethylene glycol
Yu, Weiqiang,Lu, Fang,Huang, Qianqian,Lu, Rui,Chen, Shuai,Xu, Jie
supporting information, p. 3327 - 3333 (2017/07/28)
Etherification of ethylene glycol with methanol provides a sustainable route for the production of widely used dimethoxyethane; dimethoxyethane is a green solvent and reagent that is applied in batteries and used as a potential diesel fuel additive. SAPO-34 zeolite was found to be an efficient and highly selective catalyst for this etherification via a continuous flow experiment. It achieved up to 79.4% selectivity for dimethoxyethane with around 96.7% of conversion. The relationship of the catalyst's structure and the dimethoxyethane selectivity was established via control experiments. The results indicated that the pore structure of SAPO-34 effectively limited the formation of 1,4-dioxane from activated ethylene glycol, enhanced the reaction of the activated methanol with ethylene glycol in priority, and thus resulted in high selectivity for the desired products. The continuous flow technology used in the study could efficiently promote the complete etherification of EG with methanol to maintain high selectivity for dimethoxyethane.
Ruthenium bipyridyl tethered porous organosilica: A versatile, durable and reusable heterogeneous photocatalyst
Jana, Avijit,Mondal, John,Borah, Parijat,Mondal, Sujan,Bhaumik, Asim,Zhao, Yanli
supporting information, p. 10746 - 10749 (2015/06/30)
A versatile heterogeneous photocatalysis protocol was developed by using ruthenium bipyridyl tethered porous organosilica (Ru-POS). The versatility of the Ru-POS catalyst in organo-photocatalysis was explored by (i) oxidative aromatization of Hantzsch ester, (ii) reductive dehalogenation of alkyl halides, and (iii) functional group interconversion (FGI) of alcohols to alkyl halides. This journal is