Checked by O. Vogl, B. C. Anderson, and B. C. McKusick.
1. Procedure
Caution!
Diazomethane is hazardous. Follow the directions for safe handling of
diazomethane given in earlier volumes.
3,4 All operations are carried out in a
hood.
The apparatus is shown in
f.htmig. 1.
Two 500-ml. round-bottomed flasks without standard-taper joints (which could cause
diazomethane to detonate) are used. The
gas inlet C is connected to a
cylinder of
dimethyl ether. Gas inlet
C is long enough to reach near the bottom of flask
A, but tubing
D extends only about halfway into flask
B. A
calcium chloride drying tube is attached to the
gas outlet E. Flask
B contains a
Teflon®-covered stirring bar. The pieces of the apparatus are dried in an
oven at 110°; well-dried apparatus is essential for a good yield.
Fig. 1.
A solution of
diazomethane in 200 ml. of xylene is prepared from
15.0 g. (0.146 mole) of nitrosomethylurea5 (Note
1). The
diazomethane solution is decanted into flask
A, and about
20 g. of potassium hydroxide pellets is added to the solution. The mixture is swirled for a few seconds to ensure removal of most of the water. About
4.2 g. (0.10 mole) of diazomethane is present. Flask
A is then immersed in a
water bath at 20–25°.
2,4,6-Trinitrobenzenesulfonic acid (14.7 g., 0.050 mole) (Note
2), previously dried for at least 1 hour at 80–100° (1 mm.), is placed in flask
B, which is then immersed to the level shown in
fig. 2.htm in a
bath of acetone maintained at −35° to −40° by addition of small amounts of dry ice (Note
3). About
200 ml. of dimethyl ether is rapidly poured from an ampoule into flask
B (Note
3). Flasks
A and
B are connected as shown in
fig. 2.htm, and magnetic stirring is started in flask
B. When most of the sulfonic acid has dissolved, gaseous
dimethyl ether is introduced through
C at such a rate that a rapid stream of individual bubbles passes through the
diazomethane solution in flask
A. In the course of the reaction all the acid goes into soution and is replaced by a fluffy precipitate of the oxonium salt. The introduction of
dimethyl ether is discontinued as soon as the supernatant solution in flask
B turns yellow (Note
5) and (Note
6).
2. Notes
1.
Xylene is used as the solvent instead of
diethyl ether because of its considerably lower vapor pressure.
2.
2,4,6-Trinitrobenzenesulfonic acid from Nutritional Bio-chemical Corp., Cleveland, Ohio, can be used without any purification other than drying. The checkers observed m.p.
174–177° for the dried acid.
The acid can be prepared from
picryl chloride according to the method described by Golumbic, Fruton, and Bergmann,
6 but the following modifications are recommended:
sodium metabisulfite should be used in place of
sodium bisulfite; the crude sodium salt is not recrystallized but is converted directly to the acid by the addition of
hydrochloric acid to its
acetone solution; the product is recrystallized by dissolving it in a minimum amount of hot
acetone, adding
chloroform until crystallization starts, and cooling to about 0°. Two recrystallizations yield a product with m.p.
194–196°.
3. If the level of the cooling bath is too high, or if the bath temperature is less than −40°, unnecessary condensation of
dimethyl ether occurs. If the level of the bath is too low, a brownish ring of decomposition product forms in the flask. Since the brown material is soluble in
dimethyl ether and
ethyl acetate, it does not contaminate the trimethyloxonium salt.
4. The submitters first transferred the
dimethyl ether from a cylinder to an ampoule in order to avoid the accumulation of excess water. The ampoule should have a moderately wide mouth in order to facilitate rapid transfer of
dimethyl ether.
The checkers made a mark on flask
B corresponding to a volume of 220 ml., added the acid and stirrer, immersed the flask in liquid
nitrogen, and passed in gaseous
dimethyl ether from a cylinder until the volume of condensate reached the mark.
7. The
ethyl acetate acts only as a high-boiling material that makes the subsequent vacuum filtration easier to control.
8. If the product is air-dried for more than a few seconds on the filter, it may pick up a significant amount of water. Most of the solvent that remains with the crystals should be removed under vacuum.
9. The product at this stage of purification is sufficiently pure for synthetic applications. As measured by the amount of
dimethyl ether evolved on heating, its purity is about 95%.
10. On very rapid heating, the compound effervesces at about 120–130°. It then resolidifies and melts again at
181–183°, which is the melting point of
methyl 2,4,6-trinitrobenzenesulfonate. At low heating rates, the effervescence may not be noticed.
3. Discussion
4. Merits of the Preparation
Appendix
Compounds Referenced (Chemical Abstracts Registry Number)
petroleum ether
sodium metabisulfite
calcium chloride (10043-52-4)
hydrochloric acid (7647-01-0)
acetic acid (64-19-7)
ethyl acetate (141-78-6)
diethyl ether (60-29-7)
chloroform (67-66-3)
nitrogen (7727-37-9)
sodium bisulfite (7631-90-5)
dimethyl ether (115-10-6)
acetone (67-64-1)
potassium hydroxide (1310-58-3)
xylene (106-42-3)
1,3,5-Trinitrobenzene (99-35-4)
Diazomethane (334-88-3)
Nitrosomethylurea
picryl chloride (88-88-0)
Triethyloxonium fluoborate (368-39-8)
trimethyloxonium fluoborate (420-37-1)
Trimethyloxonium 2,4,6-trinitrobenzenesulfonate (13700-00-0)
2,4,6-Trinitrobenzenesulfonic acid (2508-19-2)
methyl 2,4,6-trinitrobenzenesulfonate
hexachloroantimonate
phosphorus pentoxide (1314-56-3)
Oxonium compounds, trimethyloxonium 2,4,6-trinitrobenzenesulfonate
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