Checked by G. Swift and W. D. Emmons.
1. Procedure
A.
Acetone azine. A
500-ml., round-bottomed flask containing
145 g. (183 ml., 2.50 moles) of acetone (Note
1) is fitted with a
mechanical stirrer (Note
2) and a
dropping funnel and cooled in an
ice bath. With vigorous stirring,
65.5 g. (1.31 moles) of 100% hydrazine hydrate (Note
1) is added at such a rate that the temperature is maintained below 35°. The addition takes 20–30 minutes. The mixture is stirred for an additional 10–15 minutes before
50 g. of potassium hydroxide pellets is added with vigorous stirring and continued cooling (Note
3). The upper liquid layer is separated and allowed to stand over
25 g. of potassium hydroxide pellets for 30 minutes, with occasional swirling (Note
4). After filtration, the liquid is further dried with two successive
12.5-g. portions of potassium hydroxide. Distillation gives
120–126 g. (
86–90%) of almost colorless
acetone azine, b.p.
128–131°,
nD22 1.4538 (Note
5).
A mixture of
112 g. (1.00 mole) of acetone azine and
32 g. (1.0 mole) of anhydrous hydrazine is placed in a
300-ml. round-bottomed flask fitted with a
reflux air condenser and drying tube, and kept at 100° for 12–16 hours.
(Caution! This reaction and the subsequent distillation should be carried out behind a protective screen.) The crude product is then distilled rapidly through a
water-cooled condenser, and the colorless fraction boiling at 122–126° is collected,
nD22 1.4607 (Note
7), yielding
111–127 g. (
77–88%, (Note
7) and (Note
8)) of essentially pure
acetone hydrazone (Note
9).
2. Notes
2. A
Hershberg stirrer made of Nichrome wire is most efficient for aiding dissolution of the
potassium hydroxide added after azine formation is complete.
3. The dissolution of the
potassium hydroxide is strongly exothermic. A small proportion may remain undissolved.
4. A lower, aqueous phase may form at this stage, but the product is easily decanted from it.
6. The purity is 95–98% by this method.
3 The purity is lower (85–95%) by an alternative procedure
4 which requires separation of the
hydrazine and alkaline phases above 60°; with the latter method the submitters found that a frequent problem was the solidification of the lower phase in the
separating funnel, and in one case
a very serious fire occurred during the transfer of the hot (
ca. 100°) mixture to the separating funnel.
7. The forerun contains
hydrazine; material boiling above 126° contains much
acetone azine. With a slow rate of distillation, disproportionation occurs and the yield of
acetone hydrazone is reduced. If the forerun and material boiling above 126° are combined and reheated at 100° for 12–16 hours, they give more
acetone hydrazone on redistillation. With further repetitions of this procedure, the yield is almost quantitative.
8. The highest yields were obtained in cases where the anhydrous
hydrazine was treated with
barium oxide for several hours before use.
9. The hydrazone should be used as soon as possible. If it is stored, care must be taken to exclude moisture, which catalyzes disproportionation to
hydrazine and
acetone azine.
5,6,7 Even in the absence of moisture it disproportionates slowly at room temperature and so should be redistilled immediately before use. Old samples can be regenerated fairly satisfactorily by reheating them for 12–16 hours at 100° before redistillation, but there is always some irreversible decomposition to high-boiling products during storage.
3. Discussion
The procedure for
acetone azine is essentially that of Curtius and Thun.
5 The method for
acetone hydrazone is adapted from that of Staudinger and Gaule.
8 The hydrazone has been prepared directly from
acetone and
hydrazine, but this is much less satisfactory.
6
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