Checked by Kyo Okada and Wataru Nagata.
1. Procedure
A
300-ml., three-necked, round-bottomed flask is equipped with a magnetic stirrer, a thermometer, a glass stopper, and an efficient condenser attached to a nitrogen line with a gas bubbler (Note
1). The system is flushed with dry
nitrogen, then charged with
19.8 g. (0.100 mole) of biphenyl-2-carboxylic acid (Note
2),
80 g. (60 ml., 0.59 mole) of trichlorosilane (Note
3) and (Note
4), and
80 ml. of acetonitrile (Note
5). A low
nitrogen flow is maintained as the mixture is stirred and heated to reflux (40–45°) for 1 hour or until gas evolution ceases and the carboxylic acid has dissolved. The solution is then cooled in an
acetone–dry ice bath to at least 0°, and the glass stopper is replaced with a
100-ml., pressure-equalizing dropping funnel charged with
37.8 g. (0.264 mole) of tri-n-propylamine (Note
6) and (Note
7), which is emptied rapidly into the stirred solution. The
cooling bath is removed, and the flask contents are allowed to stir until the reaction ceases to be exothermic. A
heating mantle is then used to maintain reflux for 16 hours (Note
8), during which time the temperature rises to 70–75°.
As soon as reflux is terminated, the solution is poured rapidly into a
1-l. Erlenmeyer flask, allowed to cool, and diluted with enough
anhydrous diethyl ether (Note 9) to make the total volume about 850 ml. (Note
10). After the flask has been sealed and refrigerated for one hour, the precipitate is removed by rapid filtration (
water aspirator) through a
150-ml. Büchner funnel and washed with three
50-ml. portions of anhydrous ether. The clear yellow filtrate is concentrated as follows. A
300-ml., one-necked, round-bottomed flask is fitted with a magnetic stirring bar and a 100-mm. Vigreux column topped with a distillation head. The filtrate is placed in a
1-l., pressure-equalizing dropping funnel inserted into the top of the distillation head. Approximately 100 ml. is run down through the column into the flask, which is then heated. As
ether is removed by distillation, the remainder of the filtrate is dripped into the flask at a constant rate, and in this way the solution is concentrated into a
small flask in a continuous operation. Distillation is continued until most of the ether has been removed, and the resulting murky solution is heated at 40° (80 mm.), removing the remaining volatiles.
The Vigreux column, dropping funnel, and distilling head are then replaced by a
100-ml., pressure-equalizing dropping funnel charged with
100 ml. of methanol. With the top of the funnel left open to the atmosphere, the
methanol is added slowly to the oily flask contents (Note
11). After vigorous boiling has ceased, the solution is heated under reflux for one hour, cooled in an
ice bath, then treated slowly with a solution of
56 g. (1.0 mole) of potassium hydroxide in 25 ml. of water and
50 ml. of methanol.
2 The resulting mixture is heated under reflux for 19 hours (Note
8), dissolved in 600 ml. of water, and extracted three times with
100 ml. of ether. The extracts are combined, washed once with
50 ml. of 5 N hydrochloric acid, and dried over
anhydrous magnesium sulfate.
Ether is removed by distillation as described above, using a
300-ml., pressure-equalizing dropping funnel, a
50-ml., round-bottomed distilling flask, and a
100-mm. Vigreux column. Vacuum distillation of the remaining liquid gives
12.5–13.4 g. (
74–80%) of
2-methylbiphenyl, b.p.
76–78° (0.5 mm.),
n20D 1.5920 (Note
12) and (Note
13).
2. Notes
1. All glassware is thoroughly dried by flame or in an
oven prior to use.
3. The submitters used
trichlorosilane supplied by Union Carbide Corporation. The checkers obtained
trichlorosilane from Tokyo Chemical Industries Company, Ltd., Japan.
4. Good results may sometimes be achieved with a 4:1 or 5:1 mole ratio of
trichlorosilane to carboxylic acid. Excess
trichlorosilane is needed to compensate for losses of this volatile reactant over extended reflux periods.
5. The submitters used
reagent grade acetonitrile (Mallinckrodt Chemical Works) dried prior to use by storage over Matheson Linde type 4A molecular sieves. The checkers used reagent grade
acetonitrile obtained from Ishizu Pharmaceutical Company, Japan, dried prior to use by storage over 4A molecular sieves obtained from Nakarai Chemicals, Ltd., Japan.
6. The submitters used
tri-n-propylamine obtained from Aldrich Chemical Company, Inc., and the checkers used
tri-n-propylamine obtained from Wako Pure Chemical Industries, Ltd., Japan. Both groups stored the reagent over Linde type 4A molecular sieves prior to use.
8. Overnight reflux was chosen partly for convenience. Similar results are possible with somewhat shorter reaction times.
9. The submitters employed
anhydrous ether obtained from Mallinckrodt Chemical Works; the checkers used
anhydrous ether obtained from Wako Pure Chemical Industries, Ltd., Japan and distilled it from
sodium hydride under
nitrogen shortly prior to use.
10. The volume of ether added should be sufficient to precipitate most of the
tri-n-propylamine hydrochloride in solution. The checkers diluted to a total volume of about 1 l. to precipitate the salt more efficiently.
12. The literature
3 value for a carefully purified sample of
2-methylbiphenyl is
nD20 1.5914.
13.
1H NMR (CDCl
3), δ (multiplicity, number of protons, assignment): 2.55 (s, 3H, C
H3), 7.27 (s, 4H, C
6H4), 7.33 (s, 5H, C
6H5). IR (CHCl
3) cm.
−1: 1600 medium, 1480 medium strong (aromatic), 1380 medium (CH
3). GC analysis of the product (1.5 m. by 0.5 cm. glass
column, KF-54 on Chromosorb W, 60–80 mesh) showed a single peak with a retention time of 2.60 minutes at 170°.
3. Discussion
In a more general sense, this reduction method provides a convenient pathway for converting an aromatic carboxyl group to a methyl group (see Table I).
7 Previously, this transformation has been achieved by reduction of the acid to the alcohol with
lithium aluminum hydride, conversion of the alcohol to the tosylate, and a second reduction either with
lithium aluminum hydride, or
Raney nickel and
hydrogen.
8 Alcohols of the benzylic type have also been reduced directly with
hydrogen under pressure in the presence of various catalysts,
9 and benzoic acids have been reduced to toluenes with rhenium-type catalysts and
hydrogen at high temperatures and pressures.
10
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