Submitted by Robert M. Washburn, Ernest Levens, Charles F. Albright, and Franklin A. Billig
1.
Checked by B. C. McKusick and H. C. Miller.
1. Procedure
The apparatus consists of a
four-necked 5-l. round-bottomed Morton flask2 fitted with a
500-ml. graduated dropping funnel with a pressure-equalizing side arm, a
1-l. graduated dropping funnel of the same type, a
thermometer, an
efficient mechanical stirrer (Note
2), and an
inlet for dry nitrogen. The apparatus is thoroughly swept with dry
nitrogen, and the reaction flask is charged with
1.5 l. of anhydrous ether, dry
nitrogen (Note
3) being used for pressure transfer.
Three hundred thirty-six milliliters (312 g., 3 moles) of methyl borate is distilled directly into the 500-ml. dropping funnel shortly before starting the reaction (Note
4).
One liter (544 g., 3 moles) of a 3M ethereal solution of phenylmagnesium bromide is pressure-transferred with dry
nitrogen to the 1-l. dropping funnel (Note
5). During subsequent operations until the hydrolysis step, a positive pressure of 10–20 mm. of
nitrogen is maintained in the closed system by means of a
mercury bubbler to prevent access of atmospheric moisture. The
ether is cooled to below −60° by a
bath of Dry Ice and acetone and is kept below −60° all during the reaction (Note
6). The reactants are added to the well-stirred reaction mixture alternately in small portions, first
10 ml. of methyl borate and then
30 ml. of phenylmagnesium bromide, the rate of addition being as rapid as is possible without the temperature of the mixture rising above −60° (Note
7). Stirring is continued for an additional 20 minutes below −60° after the addition of the reagents is completed.
The stirred mixture, maintained at or below 0°, is hydrolyzed by the addition of 200 ml. of distilled water during 5 minutes. It is then neutralized by addition of a solution of
84 ml. of concentrated sulfuric acid in 1.7 l. of distilled water during 15 minutes. The mixture is transferred to a
5-l. separatory funnel, the
ether layer is separated, and the aqueous layer is extracted with three
250-ml. portions of ether.
The combined
ether layer and extracts are transferred to a 5-l. round-bottomed flask equipped with a
Hershberg stirrer,
3 a dropping funnel, a
Claisen head with a water-cooled condenser, an
electric heating mantle, and an
ice-cooled receiver (Note
8). After approximately one-half of the
ether has been removed by distillation from the stirred mixture, 1.5 l. of distilled water is added slowly while the distillation is continued until a head temperature of 100° is reached (Note
9).
While stirring is continued, the aqueous distilland is cooled in an
ice bath (Note
10). The
benzeneboronic acid, which separates as small white crystals, is collected on a
Büchner funnel and washed with
petroleum ether. The
petroleum ether removes traces of
dibenzeneborinic acid, which are seen in the hot mother liquor as globules of brown oil and which may color the product. The acid is dehydrated to
benzeneboronic anhydride by heating it in an
oven at 110° and atmospheric pressure for 6 hours (Note
11).
Benzeneboronic anhydride is obtained as a colorless solid, weight
240–247 g. (
77–79%) (Note
12), m.p.
214–216°.
2. Notes
2. The submitters found that for a preparation of this size a 1-inch Duplex Dispersator (Premier Mill Corp., Geneva, New York) operating at 7500 r.p.m. provided excellent agitation of the heterogeneous reaction mixture. For smaller preparations (1-l. flask) they found that a Stir-O-Vac (Labline, Inc., 217 N. Desplainer St., Chicago 6, Illinois) operating at 5000 r.p.m. was satisfactory. The type of agitation is very important for, whereas the submitters obtained yields of around 91%, the checkers obtained yields of only 77–80% with either a
Morton stirrer2 (excessive splashing deposited some of the reaction mixture on the warm upper walls of the flask) or a
Polytron dispersion mill type of stirrer (there was too much hold-up in the stirrer housing).
4.
Methyl borate (b.p.
68°) forms a 1:1 azeotrope (b.p. 54.6°) with
methanol (b.p.
64°).
5 Since the presence of even a small amount of
methanol reduces the yield considerably more than would be expected from the stoichiometry,
46,7 methyl borate stocks should be freshly distilled through a good column to remove as fore-run any
methyl borate-methanol azeotrope which may have been formed by hydrolysis during storage.
5.
Mallinckrodt analytical reagent grade ether, dried over
sodium, was used. The
methyl borate was the commercial product of American Potash and Chemical Corporation containing 99% ester as received. The
phenylmagnesium bromide was purchased as a 3.0M solution in ether from Arapahoe Special Products, Inc., Boulder, Colorado.
6. The yield of
benzeneboronic anhydride is highly dependent upon the reaction temperature, as the following data of the submitters show. At a reaction temperature of 15° the yield was
49%; at 0°,
76%; −15°,
86%; −30°,
92%; −45°,
92%; −60°,
99%. The yields are based on the combined first and second crops of
benzeneboronic acid.
7. At a given temperature, the maximum yield of
benzeneboronic acid and the minimum amount of by-product
dibenzeneborinic acid are obtained when neither reagent is present in excess. The addition of small increments of reactants is a convenient approximation imposed by the difficulty of adjusting stopcocks to small rates of flow. Alternatively, the
Hershberg dropping funnel8 or other metering device may be used to maintain the stoichiometry. Addition times, which depend upon the efficiency of stirring and heat transfer, vary from about 1 hour at −60° to 15 minutes at 0°.
8. Stirring is helpful during the
ether distillation to prevent superheating.
9. Small amounts of
benzene,
phenol, and
biphenyl, which may be formed in the reaction, are removed by the steam distillation. Enough water has been added to ensure solution of all of the product.
10. The product crystallizes at 43° with a temperature rise to 45°. The solubility of
benzeneboronic acid in water (g./100 g. of water) is approximately 1.1 at 0° and 2.5 at 25°; the solubility-temperature relationship is linear to at least 45°.
11. If
benzeneboronic acid rather than its anhydride is desired, it can be obtained by air-drying the moist acid in a slow stream of air nearly saturated with water. The yield of acid is
282–332 g. One can readily convert the anhydride to the acid by recrystallizing it from water.
Benzeneboronic acid gradually dehydrates to the anhydride if left open to the atmosphere at room temperature and 30–40% relative humidity. The melting point observed is that of the anhydride because the acid dehydrates before it melts.
12. The submitters report a yield of
91% and state that an additional
27 g. (
9%) of acid can be obtained from the aqueous mother liquor.
3. Discussion
The present procedure is also applicable to the synthesis of substituted benzeneboronic acids.
4 Benzeneboronic acid and its anhydride are of use as starting materials for the synthesis of
phenylboron dichloride15 and of various substituted boronic and borinic acids and esters.
7,16
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