Organic Syntheses, CV 4, 597
Submitted by George W. Cannon, Ray C. Ellis, and Joseph R. Leal
1.
Checked by R. S. Schreiber, Wm. Bradley Reid, Jr., and R. D. Birkenmeyer.
1. Procedure
A.
5-Chloro-2-pentanone. A mixture of
450 ml. of concentrated hydrochloric acid, 525 ml. of water, and
384. g. (3 moles) of α-acetyl-γ-butyrolactone (Note
1) and a boiling chip are placed in a
2-l. distilling flask fitted with a 90-cm. bulb-type condenser and a receiver immersed in an ice water bath (Note
2).
Carbon dioxide is evolved immediately. Heating of the reaction mixture is begun at once, and the temperature is raised at such a rate that the reaction mixture does not foam into the condenser. In about 10 minutes the color changes from yellow to orange to black, the effervescence begins to subside, and distillation commences. The distillation is continued as rapidly as possible (Note
3). After 900 ml. of distillate has been collected, 450 ml. of water is added to the distilling flask and another 300 ml. of distillate is collected.
The yellow organic layer in the distillate is separated (Note
4), and the aqueous layer is extracted with three
150-ml. portions of ether. The
ether extracts are combined with the organic layer and dried for 1 hour over
25 g. of calcium chloride. A saturated
calcium chloride layer forms in the bottom. The
ether solution is decanted and dried with an additional
25 g. of calcium chloride. The
ether is removed by distillation through a
30-cm. column packed with glass helices and fitted with a total condensation, variable take-off head. The residual crude
5-chloro-2-pentanone weighs
287–325 g. (
79–90%) (Note
5). When 290 g. of this material is fractionated through a wrapped
12-in. Vigreux column, the major portion boils at
70–72°/20 mm.,
n25D 1.4371, and weighs
258–264 g. (
89–91%).
B.
Methyl cyclopropyl ketone. A
2-l. three-necked flask is fitted with a sweep-type stirrer made from
-in. iron rod (Note
6), a
reflux condenser, and a
500-ml. dropping funnel. In the flask is placed a solution of
180 g. (4.5 moles) of sodium hydroxide pellets in 180 ml. of water. To this solution is added over a period of 15–20 minutes
361.5 g. (342 ml., approximately 3 moles) of the crude 5-chloro-2-pentanone (Note
7). If the reaction mixture does not begin to boil during the addition, boiling is initiated by slight heating of the flask and is continued for 1 hour. Three hundred and seventy milliliters of water is then added slowly to the reaction mixture over a 20-minute period, and the mixture is heated under reflux for an additional hour.
The condenser is arranged for distillation, and a water-ketone mixture is distilled until all the organic layer is removed from the reaction mixture. The aqueous layer of the distillate is saturated with
potassium carbonate, and the upper layer of
methyl cyclopropyl ketone is separated. The aqueous layer is extraced with two
150-ml. portions of ether. The
ether extracts and the ketone layer are combined and dried over
25 g. of calcium chloride for 1 hour. The
ether solution is decanted and dried with an additional
25 g. of calcium chloride. The dried
ether solution is fractionated through the
30-cm. column described in Part A (Note
8). The yield of
methyl cyclopropyl ketone, b.p.
110–112°,
n25D 1.4226, is
193–210 g. (
77–83%).
2. Notes
1. Available from U. S. Industrial Chemicals, Inc. Its preparation has been described by several workers.
2,3,4
2. Efficient condensation is important; otherwise some of the product is swept out by the
carbon dioxide, and the yield of the chloride is decreased.
3. Any delay in distilling the chloride results in a decrease in yield. If the reaction mixture is allowed to stand overnight before removal of the chloride, the yield is less than
50%.
4. The chloride is usually the bottom layer. However, occasionally some of it also will be found on top. If so, the addition of
50–100 ml. of ether will cause all the chloride to be in the upper layer and will facilitate separation.
5. Corresponding runs beginning with
128 g. (1 mole) of α-acetyl-γ-butyrolactone gave 107–112 g. (89–93%) of crude 5-chloro-2-pentanone. The checkers consistently obtained yields of 79–81% using U. S. Industrial Chemicals, Inc., lactone.
6. A Hershberg stirrer constructed with a

-in. iron or stainless-steel shaft is also satisfactory. Glass stirrers are not recommended because they may break.
7. The use of distilled chloride does not result in better over-all yields.
8. A
fractionating column is necessary for the separation of the
ether-ketone solution. With an ordinary distilling flask, a ketone-
ether mixture, b.p.
41°, is obtained with a resultant decrease in the yield of pure ketone. A
well-insulated or preferably heated column is necessary for good fractionation.
3. Discussion
This preparation is referenced from:
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