Checked by L. Foley, W. Jackson, and A. Brossi.
1. Procedure
A
1-l., three-necked, round-bottomed flask equipped with an efficient mechanical stirrer (Note
1), a
thermometer, and a
vent (Note
2) is placed in a
water bath and charged with
600 ml. of 98% sulfuric acid (Note
3). Powdered adamantane [
Org. Synth., Coll. Vol. 5, 16 (1973)], (100 g., 0.735 mole), is added in one portion to the stirred acid, and the mixture is heated rapidly (with the water bath) to an internal temperature of 70°. The internal temperature is then raised gradually to 80° over a 2-hour period (Note
4) while vigorous stirring is maintained (Note
5). After stirring at 80° is continued for an additional 2 hours, the temperature is raised to 82°. When almost all the
adamantane is dissolved, the residual sublimed material is scraped and rinsed from the walls of the flask (Note
1) and (Note
6). When GC analysis indicates that 2–3% of
adamantanol is present (Note
6), the hot reaction mixture is poured immediately onto 800 g. of crushed ice, giving a 1500-ml. suspension containing crude
adamantanone.
A
750-ml. portion of this suspension of crude adamantanone is transferred to a
2-l., round-bottomed flask, equipped for steam distillation (Note
7) and (Note
8), which is placed in a
heating mantle. The contents of the distillation flask are heated to 70°; the external heating is turned off (Note
9) and steam is introduced carefully through both inlet tubes (Note
10). The two layers of distillate are separated, and the aqueous layer is extracted with two
75-ml. portions of dichloromethane. This steam distillation procedure is then repeated with the second half of the suspension of crude
adamantanone. The organic extracts are combined, washed with
100 ml. of aqueous, saturated sodium chloride, dried over
anhydrous sodium sulfate, and evaporated under reduced pressure, yielding
52–53 g.. (
47–48%) of
adamantanone (Note
11), (Note
12), and (Note
13).
2. Notes
1. The stirrer should be placed just under the surface of the
sulfuric acid. The flask should be filled to at least three-quarters of its volume so the sublimed material can be rinsed from the walls with vigorous stirring.
2.
Sulfur dioxide generated during the reaction can escape through the third neck of the flask. This neck should be wide enough to prevent clogging by subliming
adamantane.
4. During this part of the reaction a vigorous evolution of
sulfur dioxide takes place. Care should be taken to ensure that the internal temperature does not rise too fast to prevent an uncontrollable increase in the evolution of the
sulfur dioxide.
5. An
adamantane layer floating on the
sulfuric acid, caused by ineffective stirring or too rapid evolution of
sulfur dioxide, can lead to heavy foaming and subsequent losses. This layer, if formed, may be brought into contact with the reaction mixture by increasing the speed of the stirrer or by lowering the bath temperature to 65–70°.
6. At this stage the reaction should be monitored carefully by GC. For this purpose samples are taken periodically from the reaction mixture, poured onto ice, extracted with
dichloromethane, washed with water, and subjected to GC. The submitters used an
F and M Model 700 gas chromatograph equipped with a 2 m. by 3 mm. glass column, filled with 80/100 mesh Chromosorb-W-Hp impregnated with 9.5% Apiezon-L and 0.5% Carbowax-20 M, at 120° with a
flame ionization detector and
nitrogen as carrier gas. To obtain a good yield of a fairly pure product, the reaction should be stopped when the amount of
1-adamantanol remaining is between 2% and 3%. Prolonged heating will give a further reduction in the
1-adamantanol content but it should be emphasized that concurrently the yield of the
adamantanone will diminish rapidly.
7. The flask is fitted with two inlet tubes, one narrow and adjustable positioned above the surface of the
adamantanone suspension, and the other reaching half-way between the bottom of the flask and the surface. Both tubes are connected to the steam supply. The flask is connected through a
splash head and a short adapter to a
1-l., three-necked, round-bottomed flask equipped with two very efficient reflux condensers each stoppered with a wad of cotton. The receiving flask is charged with
100 ml. of benzene, which, during the course of the steam distillation, begins to reflux and rinses the
adamantanone from the condensers.
Added in proof. Because of the toxicity of
benzene the submitters advise replacement of this solvent with
ethyl acetate at this point and in (Note
8).
8. The checkers found that it is advisable to use superheated steam and also to distill each portion twice. Thus when the first receiving flask fills with distillate, it is replaced with a second 1-l., round-bottom flask charged with
100 ml. of benzene and distillation is resumed.
9. Prolonged external heating will stimulate the foaming. Insulation by the heating mantle is sufficient to prevent extensive steam condensation in the distilling flask.
10. The short inlet tube above the surface (Note
7) will break the foam and enable smooth removal of the
adamantanone. When foaming is very heavy, steam is introduced only through this short inlet tube.
11. The checkers found that an additional
3 g. of
adamantanone could be obtained by extracting the combined contents of the two distillation flasks with
dichloromethane, removing the solvent under reduced pressure and steam-distilling the residue, resulting in a total yield of
55–56 g. (
50–51%).
12. The product is 97–98% pure by GC (Note
6) and is satisfactory for most purposes. If desired, the
adamantanone may be purified by either column chromatography (alumina, activity grade IV; eluent:
ether) or by treatment with
fuming sulfuric acid (20% free sulfur trioxide). For example,
8.0 g. of adamantanone is added portionwise to 40 ml. of ice-cold, fuming
sulfuric acid, and the solution is heated to 40° and maintained at this temperature for one hour. After pouring the mixture onto ice, the
adamantanone is recovered by extraction with
dichloromethane.
13. The IR spectrum (KBr) shows a strong band at 1717 with minor peaks or shoulders at 1670, 1690, 1725, and 1740 cm.
−1;
1H NMR (CDCl
3), δ 2.04 (broad s, 12H, 2C
H, 5C
H2) and 2.55 (broad s, 2H, 2C
HC=O).
3. Discussion
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