Checked by William F. Burgoyne, Christopher VanCantfort, and Robert M. Coates.
1. Procedure
A.
Trichloromethyl chloroformate. A
100-ml., three-necked, round-bottomed Pyrex flask is equipped with a thermometer, a reflux condenser protected at the top with a calcium chloride tube, and a gas-inlet tube with a coarse fritted-glass tip extending almost to the bottom of the flask. In the flask are placed
37.8 g. (0.400 mole) of freshly distilled methyl chloroformate (Note
2) and a
Teflon-coated magnetic stirring bar. The flask is illuminated with a
100-W., high-pressure, mercury-vapor lamp (Note
3) placed beside it (Note
4) and (Note
5). The
methyl chloroformate is stirred and irradiated as a slow stream of
chlorine (Note
6) is passed into the flask through the gas-inlet tube (Note
7). When the temperature reaches 30° due to the exothermic reaction, the flask is immersed in a
water bath (Note
8). The
chlorine is then passed into the solution more rapidly so as to maintain the temperature at 30–35° (Note
9). After
ca. 6.5–7 hours the colorless solution assumes the pale yellow-green color of
chlorine, which indicates that the end point of the reaction has been reached (Note
10). Distillation under reduced pressure affords
65–72 g. (
82–91%) of
trichloromethyl chloroformate as a colorless liquid, b.p.
53–55° (53 mm.) (Note
11).
2. Notes
3. The checkers used a
200-W., high-pressure, mercury-vapor lamp and the corresponding transformer which are available from the Hanovia Lamp Division, Canrad-Hanovia, Inc., 100 Chestnut St., Newark 5, New Jersey 07105. The lamp was suspended vertically in a
cylindrical, double-walled, Pyrex jacket cooled by flowing water. The inside diameter, outside diameter, and length of the cooling jacket were 3, 4, and 22 cm., respectively. The cooling jacket was clamped in place
ca. 5 cm. from the reaction vessel to allow the
cooling bath to be raised into position. The use of the 200-W. lamp did not alter the reaction time.
4. It is advisable to wrap the entire apparatus with aluminum foil to avoid exposure to UV light. The reaction solution can be observed through a small hole in the aluminum foil which is is shielded from the direct radiation of the lamp.
5. The irradiation should be started before the flow of
chlorine gas is begun to avoid the risk of explosion.
6. The checkers used
chlorine from a lecture bottle supplied by the Linde Division, Union Carbide Chemical Corp.
7.
Chlorine should be introduced slowly at first to prevent an accumulation of unreacted
chlorine in the solution and avoid the risk of a rapid, exothermic reaction. The accumulation of
chlorine is indicated by the appearance of its characteristic yellow-green color.
8. The checkers used a
15 × 7.5 cm. Pyrex crystallizing dish as a transparent water bath.
9. Once the
chlorine gas flow is properly adjusted, the solution remains colorless and the temperature stays in the 30–35° range without further adjustment until the end point is approached. However, the color and temperature should be observed frequently during the 6.5- to 7-hour reaction time.
Although this reaction can be carried out at higher temperatures, the yields are reduced, probably owing to loss of the volatile
methyl chloroformate, b.p.
71°, and/or decomposition of the product. For example, the yields of
trichloromethyl chloroformate are
ca. 75% and
55% when the chlorination is carried out at 50–55° and 85–90°, respectively.
10. The checkers judged that the end point had been reached when the yellow-green color persisted for 2–3 minutes after the
chlorine flow had been stopped. At the first appearance of the yellow-green color, the gas stream was shut off, and the color faded within
ca. 15 sec. The
chlorine flow was resumed at a slow rate until the end point was reached.
11. The product has the following spectral properties: IR (neat) cm.
−1: 1815 (C=O), 1054, 968, 912, 814, 764;
13C NMR (CDCl
3), δ (assignment): 108.37 (
CCl
3), 143.93 (
C=O).
Trichloromethyl chloroformate is stable at room temperature, but decomposes to
phosgene when heated above 300°
5 or on contact with
iron(III) oxide or charcoal.
6 Decomposition to
carbon tetrachloride and
carbon dioxide occurs on exposure to
alumina,
aluminum chloride, or
iron(III) chloride.
5,6,7,8
12. The checkers dried and purified
dioxane by distillation from the
sodium–benzophenone ketyl.
13.
3-Aminopropanoic acid (β-alanine) is available from Aldrich Chemical Company, Inc., and from the Nutritional Biochemical Division, ICN Products. The hydrochloride salt is prepared in the following manner. A solution of
89 g. (1.0 mole) of 3-aminopropanoic acid in 200 ml. of water is acidified by addition of
100 ml. (1.20 mole) of concentrated hydrochloric acid and concentrated to a white solid with a
rotary evaporator. The solid is pulverized to a fine powder and dried at 60° under reduced pressure, yielding
113–125 g. (
90–100%) of
3-aminopropanoic acid hydrochloride.
14. Although the reaction can be carried out with an equimolar amount of
trichloromethyl chloroformate, a longer time (15–20 hours) is required to reach completion, and the yield is reduced somewhat. If a 1.5–2.0-fold excess of
trichloromethyl chloroformate is used, the reaction time is decreased to
ca. 5 hours and the yield is increased to
90–95%.
15. The checkers heated the suspension for a total of 10 hours, 7–8 hours having been required to dissolve the solid completely. The reaction time may depend on the particle size of the hydrochloride salt and the rate of stirring.
16. The submitters advise that the distillation be carried out rapidly to avoid the formation of a tarry residue.
17. The spectral properties of
3-isocyanatopropanoyl chloride are as follows: IR (liquid film) cm.
−1: 2278 (N=C=O), 1795 (O=C-Cl);
1H NMR (CDCl
3), δ (multiplicity, coupling constant
J in Hz., number of protons, assignment): 3.17 (t,
J = 6, 2H, C
H2CH
2N=C=O), 3.67 (t,
J = 6, 2H, CH
2C
H2N=C=O);
13C NMR (CDCl
3), δ (assignment): 38.3 (CH
2CH
2N=C=O), 47.6 (
CH
2CH
2N=C=O), 123.0 (N=C=O), 171.6 (O=
C-Cl). A small peak at δ 67.1 in the
13C NMR spectrum of the product obtained by the checkers was attributed to a small amount of
dioxane.
3. Discussion
Trichloromethyl chloroformate is synthetically useful as a substitute for
phosgene, which, owing to its high volatility and toxicity, presents a severe hazard in the laboratory. Although
trichloromethyl chloroformate is toxic, it is a dense and less volatile liquid (b.p.
128°,
d1515 1.65), having a vapor pressure of only 10 mm. at 20°. Consequently it is more easily handled in a safe manner than
phosgene.
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