Ethylene oxide

Ethylene oxide is an organic compound with the chemical formula . It is a cyclic ether and the simplest epoxide: a three-membered ring consisting of one oxygen atom and two carbon atoms. Ethylene oxide is a colorless and flammable gas with a faintly sweet odor. Because it is a strained ring, ethylene oxide easily participates in a number of addition reactions that result in ring-opening. Ethylene oxide is with acetaldehyde and with vinyl alcohol. Ethylene oxide is industrially produced by oxidation of ethylene in the presence of a silver catalyst.

The reactivity that is responsible for many of ethylene oxide's hazards also makes it useful. Although too dangerous for direct household use and generally unfamiliar to consumers, ethylene oxide is used for making many consumer products as well as non-consumer chemicals and intermediates. These products include detergents, thickeners, solvents, plastics, and various organic chemicals such as ethylene glycol, ethanolamines, simple and complex glycols, , and other compounds. Although it is a vital raw material with diverse applications, including the manufacture of products like polysorbate 20 and polyethylene glycol (PEG) that are often more effective and less toxic than alternative materials, ethylene oxide itself is a very hazardous substance. At room temperature it is a very flammable, carcinogenic, mutagenicity, irritating; and anaesthetic gas.

Ethylene oxide is a surface disinfectant that is widely used in hospitals and the medical equipment industry to replace steam in the sterilization of heat-sensitive tools and equipment, such as disposable plastic syringes.

It is so flammable and extremely explosive that it is used as a main component of thermobaric weapons; therefore, it is commonly handled and shipped as a refrigerated liquid to control its hazardous nature.Rebsdat, Siegfried and Mayer, Dieter (2005) "Ethylene Oxide" in Ullmann's Encyclopedia of Industrial Chemistry. Wiley-VCH, Weinheim. . Ethylene Oxide Sterilization: Are ETO Treated Spices Safe?, SuperFoodly, 10 April 2017

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History

Ethylene oxide was first reported in 1859 by the France chemist Charles-Adolphe Wurtz, who prepared it by treating 2-chloroethanol with potassium hydroxide:

Wurtz measured the boiling point of ethylene oxide as , slightly higher than the present value, and discovered the ability of ethylene oxide to react with acids and salts of metals. Wurtz mistakenly assumed that ethylene oxide has the properties of an organic base. This misconception persisted until 1896, when Georg Bredig found that ethylene oxide is not an electrolyte. That it differed from other — particularly by its propensity to engage in the addition reactions typical of unsaturated compounds — had long been a matter of debate. The heterocyclic triangular structure of ethylene oxide was proposed by 1868 or earlier.Eugen F. von Gorup-Besanez, ed., Lehrbuch der organischen Chemie für den Unterricht auf Universitäten ... Textbook, 3rd ed. (Braunschweig, Germany: Friedrich Vieweg und Sohn, 1868), vol. 2, p. 286.
See also p. 253 of the 1876 edition: Eugen F. von Gorup-Besanez, ed., Lehrbuch der organischen Chemie für den Unterricht auf Universitäten ..., 5th ed. (Braunschweig, Germany: Friedrich Vieweg und Sohn, 1876), vol. 2.

Wurtz's 1859 synthesis long remained the only method of preparing ethylene oxide, despite numerous attempts, including by Wurtz himself, to produce ethylene oxide directly from ethylene.

(1994). 9780471485148, John Wiley & Sons. ISBN 9780471485148

Only in 1931 did French chemist Theodore Lefort develop a method of direct oxidation of ethylene in the presence of silver catalyst.Lefort, T.E. (23 April 1935) "Process for the production of ethylene oxide". Since 1940, almost all industrial production of ethylene oxide has relied on this process. Sterilization by ethylene oxide for the preservation of was patented in 1938 by the United States chemist Lloyd Hall. Ethylene oxide achieved industrial importance during World War I as a precursor to both the coolant ethylene glycol and the chemical weapon mustard gas.

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Molecular structure and properties

The epoxy cycle of ethylene oxide is an almost regular triangle with bond angles of about 60° and a significant angular strain corresponding to the energy of 105 kJ/mol.

Traven VF (2025). 9785946281720, ECC "Academkniga". ISBN 9785946281720

For comparison, in alcohols the C–O–H angle is about 110°; in , the C–O–C angle is 120°. The moment of inertia about each of the principal axes are I_A=, I_B= and I_C=.

The relative instability of the carbon-oxygen bonds in the molecule is revealed by the comparison in the table of the energy required to break two C–O bonds in the ethylene oxide or one C–O bond in ethanol and dimethyl ether:

(cleavage of two bonds)	354.38	Calculated, from atomic enthalpies
(breaking one bond)	405.85	Electron impact
(breaking one bond)	334.72	Calculated using enthalpies of radicals formation

This instability correlates with its high reactivity, explaining the ease of its ring-opening reactions (see Chemical properties).

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Physical properties

Ethylene oxide is a colorless gas at and is a mobile liquid at – viscosity of liquid ethylene oxide at 0 °C is about 5.5 times lower than that of water. The gas has a characteristic sweet odor of ether, noticeable when its concentration in air exceeds 500ppm. Ethylene oxide is readily soluble in water, ethanol, diethyl ether, and many organic solvents.

Main thermodynamical constants are:

• The surface tension of liquid ethylene oxide, at the interface with its own vapor, is at and at .
• The boiling point increases with the vapor pressure as follows: (), (), and ().
• Viscosity decreases with temperature with the values of 0.577kPa·s at , 0.488 kPa·s at , 0.394kPa·s at , and 0.320kPa·s at .

Between , vapor pressure p (in mmHg) varies with temperature ( T in °C) as

$\backslash lg\; p=6.251\; -\; \backslash frac\{1115.1\}\{244.14\; +\; T\}$.

+ Properties of liquid ethylene oxide
−40	8.35	0	628.6	0.9488	1878	0.20
−20	25.73	38.8	605.4	0.9232	1912	0.18
0	65.82	77.3	581.7	0.8969	1954	0.16
20	145.8	115.3	557.3	0.8697	2008	0.15
40	288.4	153.2	532.1	0.8413	2092	0.14
60	521.2	191.8	505.7	0.8108	2247	0.14
80	875.4	232.6	477.4	0.7794	2426	0.14
100	1385.4	277.8	445.5	0.7443	2782	0.13
120	2088	330.4	407.5	0.7052	3293	N/A*
140	3020	393.5	359.4	0.6609	4225	N/A
160	4224	469.2	297.1	0.608	N/A	N/A
180	5741	551.2	222.5	0.533	N/A	N/A
195.8	7191	N/A	N/A	N/A	N/A	N/A

*N/A – data not available.

+ Properties of ethylene oxide vapor
298	242.4	−52.63	−13.10	N/A	N/A	48.28
300	242.8	−52.72	−12.84	9.0	0.012	48.53
400	258.7	−56.53	1.05	13.5	0.025	61.71
500	274.0	−59.62	15.82	15.4	0.038	75.44
600	288.8	−62.13	31.13	18.2	0.056	86.27
700	302.8	−64.10	46.86	20.9	0.075	95.31
800	316.0	−65.61	62.80	N/A	0.090	102.9

*N/A – data not available.

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Chemical properties

Ethylene oxide readily reacts with diverse compounds with opening of the ring. Its typical reactions are with nucleophiles which proceed via the S_N2 mechanism both in acidic (weak nucleophiles: water, alcohols) and alkaline media (strong nucleophiles: OH⁻, RO⁻, NH₃, RNH₂, RR'NH, etc.). The general reaction scheme is

and more specific reactions are described below.

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Addition of water and alcohols

Aqueous solutions of ethylene oxide are rather stable and can exist for a long time without any noticeable chemical reaction. However adding a small amount of acid, such as strongly diluted sulfuric acid, immediately leads to the formation of ethylene glycol, even at room temperature:

(CH₂CH₂)O + H₂O → HO–CH₂CH₂–OH

The reaction also occurs in the gas phase, in the presence of a phosphoric acid salt as a catalyst.

The reaction is usually carried out at about with a large excess of water, in order to prevent the reaction of the formed ethylene glycol with ethylene oxide that would form di- and triethylene glycol:

2 (CH₂CH₂)O + H₂O → HO–CH₂CH₂–O–CH₂CH₂–OH

3 (CH₂CH₂)O + H₂O → HO–CH₂CH₂–O–CH₂CH₂–O–CH₂CH₂–OH

The use of alkaline catalysts may lead to the formation of polyethylene glycol:

n (CH₂CH₂)O + H₂O → HO–(–CH₂CH₂–O–)_n–H

Reactions with alcohols proceed similarly yielding ethylene glycol ethers:

(CH₂CH₂)O + C₂H₅OH → HO–CH₂CH₂–OC₂H₅

2 (CH₂CH₂)O + C₂H₅OH → HO–CH₂CH₂–O–CH₂CH₂–OC₂H₅

Reactions with lower alcohols occur less actively than with water and require more severe conditions, such as heating to and pressurizing to and adding an acid or alkali catalyst.

Reactions of ethylene oxide with fatty alcohols proceed in the presence of sodium metal, sodium hydroxide, or boron trifluoride and are used for the synthesis of surfactants.

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Addition of carboxylic acids and their derivatives

Reactions of ethylene oxide with in the presence of a catalyst results in glycol mono- and diesters:

(CH₂CH₂)O + CH₃CO₂H → HOCH₂CH₂–O₂CCH₃

(CH₂CH₂)O + (CH₃CO)₂O → CH₃CO₂CH₂CH₂O₂CCH₃

The addition of acid proceeds similarly:

(CH₂CH₂)O + CH₃CONH₂ → HOCH₂CH₂NHC(O)CH₃

Addition of ethylene oxide to higher carboxylic acids is carried out at elevated temperatures (typically ) and pressure () in an inert atmosphere, in presence of an alkaline catalyst (concentration 0.01–2%), such as hydroxide or carbonate of sodium or potassium.

(1998). 9780824799977, CRC Press. . ISBN 9780824799977

The carboxylate ion acts as nucleophile in the reaction:

(CH₂CH₂)O + RCO₂⁻ → RCO₂CH₂CH₂O⁻

RCO₂CH₂CH₂O⁻ + RCO₂H → RCO₂CH₂CH₂OH + RCO₂⁻

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Adding ammonia and amines

Ethylene oxide reacts with ammonia forming a mixture of mono-, di-, and tri- . The reaction is stimulated by adding a small amount of water.

(CH₂CH₂)O + NH₃ → HO–CH₂CH₂–NH₂

2 (CH₂CH₂)O + NH₃ → (HO–CH₂CH₂)₂NH

3 (CH₂CH₂)O + NH₃ → (HO–CH₂CH₂)₃N

Similarly proceed the reactions with primary and secondary amines:

(CH₂CH₂)O + RNH₂ → HO–CH₂CH₂–NHR

Dialkylamino ethanols can further react with ethylene oxide, forming amino polyethylene glycols:

n (CH₂CH₂)O + R₂NCH₂CH₂OH → R₂NCH₂CH₂O–(–CH₂CH₂O–)_n–H

Trimethylamine reacts with ethylene oxide in the presence of water, forming choline:

(2025). 9785819400678 ISBN 9785819400678

(CH₂CH₂)O + (CH₃)₃N + H₂O → HOCH₂CH₂N⁺OH⁻

Aromatic primary and secondary amines also react with ethylene oxide, forming the corresponding arylamino alcohols.

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Halide addition Ethylene oxide readily reacts with aqueous solutions of hydrochloric, hydrobromic acid, and to form . The reaction occurs easier with the last two acids:

(CH₂CH₂)O + HCl → HO–CH₂CH₂–Cl

The reaction with these acids competes with the acid-catalyzed hydration of ethylene oxide; therefore, there is always a by-product of ethylene glycol with an admixture of diethylene glycol. For a cleaner product, the reaction is conducted in the gas phase or in an organic solvent.

Ethylene fluorohydrin is obtained differently, by boiling hydrogen fluoride with a 5–6% solution of ethylene oxide in diethyl ether. The ether normally has a water content of 1.5–2%; in absence of water, ethylene oxide polymerizes.

Halohydrins can also be obtained by passing ethylene oxide through aqueous solutions of metal halides:

2 (CH₂CH₂)O + CuCl₂ + 2 H₂O → 2 HO–CH₂CH₂–Cl + Cu(OH)₂↓

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Metalorganic addition Interaction of ethylene oxide with organomagnesium compounds, which are Grignard reagents, can be regarded as nucleophilic substitution influenced by carbanion organometallic compounds. The final product of the reaction is a primary alcohol:

(CH2CH2)O{} + RMgBr -> R-CH2CH2-OMgBr ->\ce{H2O}

\overset{primary~alcohol}{R-CH2CH2-OH}

Similar mechanism is valid for other organometallic compounds, such as alkyl lithium:

(CH2CH2)O{} + \overset{alkyl~lithium}{RLi} -> R-CH2CH2-OLi ->\ce{H2O} R-CH2CH2-OH

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Other addition reactions

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Addition of hydrogen cyanide Ethylene oxide easily reacts with hydrogen cyanide forming ethylene cyanohydrin:

(CH₂CH₂)O + HCN → HO–CH₂CH₂–CN

A slightly chilled (10–20 °C) aqueous solution of calcium cyanide can be used instead of HCN:

2 (CH₂CH₂)O + Ca(CN)₂ + 2 H₂O → 2 HO–CH₂CH₂–CN + Ca(OH)₂

Ethylene cyanohydrin easily loses water, producing acrylonitrile:

HO–CH₂CH₂–CN → CH₂=CH–CN + H₂O

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Addition of hydrogen sulfide and mercaptans When reacting with the hydrogen sulfide, ethylene oxide forms 2-mercaptoethanol and thiodiglycol, and with alkylmercaptans it produces 2-alkyl mercaptoetanol:

(CH₂CH₂)O + H₂S → HO–CH₂CH₂–HS

2 (CH₂CH₂)O + H₂S → (HO–CH₂CH₂)₂S

(CH₂CH₂)O + RHS → HO–CH₂CH₂–SR

The excess of ethylene oxide with an aqueous solution of hydrogen sulfide leads to the tris-(hydroxyethyl) sulfonyl hydroxide:

3 (CH₂CH₂)O + H₂S → (HO–CH₂CH₂)₃S⁺OH⁻

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Addition of nitrous and nitric acids Reaction of ethylene oxide with aqueous solutions of barium nitrite, calcium nitrite, magnesium nitrite, zinc nitrite, or sodium nitrite leads to the formation of 2-nitroethanol:

2 (CH₂CH₂)O + Ca(NO₂)₂ + 2 H₂O → 2 HO–CH₂CH₂–NO₂ + Ca(OH)₂

With nitric acid, ethylene oxide forms mono- and dinitroglycols:

(CH2CH2)O{} + \overset{nitric\atop acid}{HNO3} -> HO-CH2CH2-ONO2 ->\ce{+HNO3} \ce{-H2O} O2NO-CH2CH2-ONO_2

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Reaction with compounds containing active methylene groups In the presence of , reactions of ethylene oxide with compounds containing active methylene group leads to the formation of butyrolactones:

Vogel, A. I. (1989). 9780582462366, Longman Scientific & Technical. . ISBN 9780582462366

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Alkylation of aromatic compounds Ethylene oxide enters into the Friedel–Crafts reaction with benzene to form phenethyl alcohol:

Styrene can be obtained in one stage if this reaction is conducted at elevated temperatures () and pressures (), in presence of an aluminosilicate catalyst.Watson, James M. and Forward, Cleve (17 April 1984) "Reaction of benzene with ethylene oxide to produce styrene"

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Synthesis of crown ethers A series of polynomial heterocyclic compounds, known as , can be synthesized with ethylene oxide. One method is the cationic cyclopolymerization of ethylene oxide, limiting the size of the formed cycle:

Hiraoka M. (1982). 9784061394445, Kodansha. ISBN 9784061394445

n (CH₂CH₂)O → (–CH₂CH₂–O–) _n

To suppress the formation of other linear polymers the reaction is carried out in a highly dilute solution.

Reaction of ethylene oxide with sulfur dioxide in the presence of caesium salts leads to the formation of an 11-membered heterocyclic compound which has the complexing properties of crown ethers:

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Isomerization When heated to about , or to in the presence of a catalyst (aluminium oxide, phosphoric acid, etc.), ethylene oxide isomerization into acetaldehyde:

(2025). 9785819400678 ISBN 9785819400678

(CH2CH2)O ->\ce{200^\circ \ce{Al2O3} \overset{acetaldehyde}{CH3CHO}

The radical mechanism was proposed to explain this reaction in the gas phase; it comprises the following stages:

In reaction (), M refers to the wall of the reaction vessel or to a heterogeneous catalyst. The moiety CH₃CHO* represents a short-lived (lifetime of 10^−8.5 seconds), activated molecule of acetaldehyde. Its excess energy is about 355.6 kJ/mol, which exceeds by 29.3 kJ/mol the binding energy of the C-C bond in acetaldehyde.

In absence of a catalyst, the thermal isomerization of ethylene oxide is never selective and apart from acetaldehyde yields significant amount of by-products (see section Thermal decomposition).

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Reduction reaction Ethylene oxide can be hydrogenated into ethanol in the presence of a catalyst, such as nickel, platinum, palladium, , lithium aluminium hydride, and some other .

Hudlický, M. (1984). 9780853123453, Ellis Horwood Limited. ISBN 9780853123453

(CH2CH2)O{} + H2 ->{}\atop\ce{Ni, \ce{80^\circ \underset{ethanol}{C2H5OH}

Conversely, with some other catalysts, ethylene oxide may be reduced by hydrogen to ethylene with the yield up to 70%. The reduction catalysts include mixtures of zinc dust and acetic acid, of lithium aluminium hydride with titanium trichloride (the reducing agent is actually titanium dichloride, formed by the reaction between LiAlH₄ and TiCl₃) and of iron(III) chloride with butyllithium in tetrahydrofuran.

(CH2CH2)O{} + H2 ->[{}\atop\ce

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