Organic Syntheses, CV 5, 1018
Submitted by S. Hünig, H. Quast, W. Brenninger, and E. Frankenfield
1.
Checked by R. A. Schwartz and K. B. Wiberg.
1. Procedure
Caution!
Tetramethyl-p-phenylenediamine may induce a painful dermatitis when brought into contact with the skin.
2 Suitable precautions should be taken to avoid such contact.
In a
2-l. three-necked flask fitted with a
stirrer,
thermometer, and
pressure-compensated dropping funnel are placed
54 g. (0.5 mole) of powdered p-phenylenediamine (Note
1),
310 g. (3.7 mole) of sodium bicarbonate, and 250 ml. of water. The temperature of the solution is maintained at 18–22° using an
ice bath while
320 ml. (3.4 mole) of dimethyl sulfate (Note
2) is added with stirring over a 30- to 50-minute period.
Carbon dioxide is evolved vigorously and a transient purple color is developed; it changes to a brown tinge later on.
When the addition of
dimethyl sulfate is complete, stirring is continued for 1 hour at 20–25°. Then the temperature is raised to 60–65° during 10 minutes (Note
3) and is kept at this value until the evolution of
carbon dioxide ceases. After the addition of 250 ml. of cold water, the reaction flask is cooled rapidly in an ice bath and
100 ml. of ethanolamine (Note
4) is added. The resultant crystalline slurry is removed from the flask, and the apparatus is rearranged as indicated in (Note
5), using an upright condenser between the
dropping funnel (Note
6) and the receiving flask.
To the reaction flask is added
200 ml. of ethanolamine, and it is heated to 140° with stirring. The slurry above is added in moderate portions over a 40- to 50-minute period (Note
7). When the heating bath is maintained at 230–240°, the addition of the slurry should provide an inner temperature at 120–140° as the water and oily product distill. After the addition is complete, the dropping funnel is rinsed with 100–150 ml. of water. As soon as the inner temperature has reached 160°,
50 ml. of ethanolamine is added and the temperature is maintained at 160–170° for 20 minutes. Water (50 ml.) is added through the dropping funnel to initiate a rapid steam distillation. Steam distillation is continued by the addition of 50-ml. portions of water at an inner temperature of 120–140° and a bath temperature of 230–240° until no more oil appears in the distillate (Note
8).
The oily product solidifies on cooling to about 20°, forming white lumps. After filtration by suction, the lumps are crushed, filtered, and washed four times with 50-ml. portions of ice water. Drying over silica gel in a vacuum gives 62–72 g. (82–88%) of white glistening scales, m.p. 51°.
2. Notes
5. The apparatus shown in
f.htmig. 1 is suitable for this step. It is essential that the
condenser be very effective since the steam distillation is very rapid. If vapor is lost from the top of an internal coil condenser, cold towels placed on the outside of the condenser will provide additional cooling.
Fig. 1
6. The dropping funnel should have a stopcock bore as large as possible.
7. Stirring and addition of only 40–50 ml. of the slurry into the dropping funnel should avoid obstruction of the stopcock. The use of a thin metal wire is sometimes helpful.
8. Transient blue colors in the distillate result from autoxidation. They do not, however, affect the purity of the final product.
3. Discussion
The present procedure
9 combines two general methods described earlier.
10,11 It is conveniently carried out and gives a substantially higher yield than previous methods.
Dimethyl sulfate in the presence of aqueous
sodium bicarbonate selectively methylates aromatic amines under mild conditions to give quaternary salts without affecting phenolic
hydroxy groups present in the molecule. If the quaternization step is sterically hindered, the reaction stops at the tertiary amine stage.
10 Heterocyclic compounds may also be converted to quaternary salts in high yield, two or more methyl groups being introduced in one step.
12 The rate of reaction may conveniently be followed by observing the
carbon dioxide evolution.
Dealkylation of quaternary ammonium salts using
ethanolamine is more convenient than the use of aqueous
ammonia in
sealed tubes at high temperatures.
10 Ethanolamine may be replaced by other ethanolamines.
13 The reaction leads to preferential removal of methyl groups.
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