Organic Syntheses, CV 5, 684
Submitted by William C. Kuryla and John E. Hyre
1.
Checked by Earl M. Levi and Peter Yates.
1. Procedure
In a
dry 1-l. five-necked flask equipped with a mechanical stirrer, a reflux condenser (Note
1), a
thermometer, a
nitrogen inlet, and a
stoppered port (Note
2) are placed
152 g. (2.00 moles) of 2-methoxyethanol (Note
3) and
50 g. of xylene (Note
4). A constant dry
nitrogen purge is maintained on the apparatus throughout the following operations (Note
5).
Metallic sodium (46.0 g., 2.00 moles) is added in small chunks through the stoppered port to the stirred reaction mixture over a 2-hour period at a temperature of 130–150°. After all the
sodium has reacted (Note
6), heating is discontinued, and
120 g. (1.24 moles) of vinylidene chloride (Note
7) is added dropwise to the stirred reaction mixture over a 20-minute period. During the addition of
vinylidene chloride the reaction mixture becomes dark, and its temperature increases rapidly from an initial 140° to a maximum of 170–175°. It then decreases as addition continues, and concomitant precipitation of
sodium chloride is noted. Stirring is continued for an additional 10 minutes after completion of the addition of
vinylidene chloride.
Anhydrous diethyl ether (100 ml.) is slowly added, serving both to reduce the viscosity and to cool the reaction mixture to about 60°. This mixture is then filtered through a
medium-grade fritted-glass funnel, and the
sodium chloride cake is washed with several
20-ml. portions of fresh ether (Note
8).
The ethereal filtrate and washings are distilled under reduced pressure (Note
9) with the use of a
6-in. Vigreux column, and pure
ketene di(2-methoxyethyl) acetal (Note
10) is obtained; b.p.
81–84° (2.0 mm.),
n25D 1.4411, yield
98–132 g. (
56–75%). The infrared spectrum of the product shows a very strong C=C absorption band at 1640 cm.
−1.
2. Notes
1. A dry ice type of condenser has been found to be the most satisfactory because of the low boiling point (32°) of the
vinylidene chloride. An efficient
water-cooled condenser is satisfactory, however.
2. An addition funnel is fitted in this port after the
sodium addition is complete.
4.
Xylene (analytical reagent grade) from Mallinckrodt Chemical Works was distilled from
sodium before use.
5. This is essential to avoid both the excessive oxidation of the reactants and the danger of a sodium-sparked fire.
6. Small amounts of metallic
sodium, such as a few
very small spheres floating in the reaction mass, are tolerable as long as dry
nitrogen is being continuously passed through the reaction flask. A slow
nitrogen purge is also maintained on the apparatus during the addition of the
vinylidene chloride. The checkers found that appreciable amounts of
sodium remained unconsumed after 3.5 hours; they added more
2-methoxyethanol (10–12 g.) to complete the reaction (significant loss of this reagent appeared to occur from the port during addition of the
sodium).
8. The
sodium chloride cake is washed with as many
20-ml. portions of ether as are required to make the filtrate essentially colorless (usually four or five).
9. The
diethyl ether is collected directly into
traps cooled in dry ice-acetone.
10. The directions of McElvain and Kundiger
2 regarding the storage of ketene acetals should be followed. The submitters have found that storage at 0°, in a bottle which was previously washed with a hot concentrated caustic solution, is satisfactory.
3. Discussion
4. Merits of the Preparation
This synthetic process is applicable to the preparation of other ketene acetal derivatives of β-alkoxy alcohols. Examples include the
ketene acetal derivatives of tetrahydrofurfuryl alcohol and 1-methoxy-2-propanol.
3 There are a number of advantages in its use, including a simple, time-saving procedure, readily available and inexpensive reagents, and good yields of ketene acetal obtained by a
one-step method.
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