Organic Syntheses, CV 5, 162
Submitted by Bernard Loev, Minerva F. Kormendy, and Marjorie M. Goodman
1.
Checked by David C. Armbruster and William D. Emmons.
1. Procedure
Caution! Because of the acrid nature of
trifluoroacetic acid and the possibility of the evolution of toxic fumes the reaction should be carried out in a
hood.
A solution of
14.8 g. (0.20 mole) of t-butyl alcohol in
125 ml. of benzene (Note
1) is placed in a
500-ml. three-necked flask equipped with a
stirrer, a
thermometer, and an
addition funnel, and
26.0 g. (0.40 mole) of sodium cyanate (Note
2) is added. The suspension is stirred as
slowly as possible (
ca. 120 r.p.m.; (Note
3)) while
48.0 g. (31.2 ml., 0.42 mole) of trifluoroacetic acid is added dropwise at a rapid rate. The temperature slowly rises to about 37° after three-quarters of the
trifluoroacetic acid has been added (
ca. 7 minutes). At this point (Note
4) the mixture is cooled to 33–35° by brief immersion in an
ice-water bath, then the addition is continued. When the addition of the acid is completed (10–12 minutes total time), the temperature slowly rises to 40° and then gradually subsides. Slow stirring is continued overnight (Note
5) at room temperature.
The mixture is treated with 35 ml. of water (Note
6) and stirred vigorously for a few minutes. The
benzene layer is decanted, and the aqueous slurry is rinsed with two
125-ml. portions of benzene (Note
7). The combined organic extracts are washed once with
100 ml. of aqueous 5% sodium hydroxide (Note
8) and with 100 ml. of water, dried over anhydrous
magnesium sulfate, and filtered. The solvent is removed by distillation under reduced pressure, preferably on a
rotary evaporator, from a water bath kept at 30° (Note
9) to give
17.7–22.0 g. (
76–94%) of
t-butyl carbamate as white needles, m.p.
104–109° (Note
10). The product may be recrystallized from
hexane (Note
11); m.p.
107–109° (Note
12).
2. Notes
1. The reagents should not be dried, as traces of moisture catalyze the reaction. The choice of solvent for this type of reaction markedly affects the yield; for most alcohols the use of
benzene or
methylene chloride gives yields superior to those obtained in other solvents.
2.
Sodium cyanate cannot be replaced by other cyanates (potassium, ammonium, etc.), for the yields are then drastically lowered.
3. Vigorous agitation markedly lowers the yield; stirring rates of 40–120 r.p.m. are optimum.
4. The temperature may rise to 40°; within the range 20–50° the temperature has little effect on the yield.
5. A contact time of 3–4 hours is sufficient, but it is convenient to stir the reaction mixture overnight. The yield is slightly higher after this additional time.
6. Only a limited amount of water is added at this point because
t-butyl carbamate has some solubility in the resulting aqueous slurry. With water-insoluble carbamates the amount of water added is immaterial.
7. The checkers found that quantitative recovery of the
benzene layer by decantation was impossible, so that in the final
benzene rinse the mixture was poured into a graduated cylinder, and the
benzene layer was quantitatively removed by a syringe.
8. The alkaline wash serves to hydrolyze a small amount of
t-butyl N-trifluoroacetylcarbamate which occasionally forms. It is not clear why this by-product forms on some occasions but not on others under apparently identical conditions. The checkers found in every case that upon standing the alkaline wash deposited 1–2 g. (after drying) of white crystals which was shown to be identical with the
t-butyl carbamate obtained as the main crop. This amount is included in the yield.
9. Most carbamates, including those of high molecular weight, are volatile. They are generally thermally unstable until they are purified.
10. The melting range varies markedly with the rate of heating, the temperature at which the sample is put into the bath, the solvent used, and the crystal form of the product. The compound at this stage is analytically pure and gives a single spot on thin-layer chromatography.
11. The carbamate may also be recrystallized from water in somewhat lower recovery. With either solvent, extensive heating should be avoided since a considerable amount of product is lost by volatilization. The checkers found that a relatively large volume of
hexane was required for recrystallization and therefore used a
1:1 benzene-hexane or
1:1 benzene-ligroin solvent system for the recrystallization.
12. The reported melting points range from
108° to 110°.
2,3,4,5
3. Discussion
Although numerous methods are known for the synthesis of carbamates of primary and secondary alcohols,
6 they are not satisfactory for the preparation of carbamates of tertiary alcohols.
7,8 t-Butyl carbamate was first obtained by reaction of
sodium t-butoxide with
phosgene and
thionyl chloride at −60°, followed by reaction with concentrated aqueous
ammonia; the overall yield was less than 20%.
2 This procedure, however, was found to be unsuitable for the preparation of carbamates of other tertiary alcohols.
8 Carbamates have been prepared by the reaction of
phenyl chloroformate (prepared from
phenol and
phosgene at −60°) with a tertiary alcohol in
pyridine, followed by treatment with
liquid ammonia.
8 A variation of this procedure involves hydrazinolysis of
phenyl t-butyl carbonate, prepared as described above, conversion to the azide, and ammonolysis.
3,4 t-Butyl carbamate has also been prepared by a four-step procedure that starts with the preparation of
t-butyl ethyl oxalate from
ethoxalyl chloride. This mixed ester was converted to
t-butyl oxamate, which was dehydrated to
t-butyl cyanoformate, and this was treated with
ammonia.
4
The carbamates of tertiary acetylenic alcohols have also been made by reaction of these alcohols with
sodium cyanate in
trifluoroacetic acid.
9 The yields by this procedure are significantly lower than those obtained by the present modification, which is essentially that described by Loev and Kormendy.
5
4. Merits of the Preparation
This one-step procedure is a convenient and general method for the preparation of carbamates. It is substantially simpler, quicker, and safer than the multistep methods hitherto used for the preparation of carbamates of tertiary alcohols. This procedure is applicable to the preparation of carbamates of primary, secondary, and tertiary alcohols and mercaptans, polyhydric alcohols, acetylenic alcohols, phenols, and oximes. It has also been extended to the preparation of carbamyl derivatives (
i.e., ureas) of inert (non-basic) amines.
10
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