Checked by G. Crass, M. Pohmakotr, and D. Seebach.
1. Procedure
A.
Tetrachlorobenzobarrelene. A
carefully dried, 5-l., three-necked, round-bottomed flask equipped with a large magnetic stirring bar, a low-temperature thermometer, a 500-ml., pressure-equalizing dropping funnel bearing a gas-inlet tube, and a Nujol bubbler (Note
1) is charged with
28.5 g. (0.100 mole) of hexachlorobenzene (Note
2). The apparatus is flushed with
argon or
nitrogen (Note
3) before
600 ml. of dry diethyl ether (Note
4) is added. The resulting suspension is stirred and cooled to −72° to −78° in a
4-l. acetone–dry ice bath. A solution of
n-butyllithium (0.110 mole) in
hexane (Note
5) is added over a 30-minute period such that the temperature does not exceed −70° (Note
6). The mixture is then allowed to warm to −60° over an additional 1.5 hours.
Four liters of dry, thiophene-free benzene (Note
4) is added to the
pentachlorophenyllithium solution (Note
7) over a 1-hour interval, during which the temperature rises to
ca. + 10° (Note
8). The mixture is allowed to warm slowly to room temperature over a period of at least 14 hours and then is heated at +30° for another 2 hours to ensure complete reaction (Note
9). A
10-g. portion of solid ammonium chloride is added, and 15 minutes later the contents of the flask are filtered through
20 g. of Celite. The volume of the filtrate is reduced to 75 ml. with a
rotary evaporator, and
100 g. of alumina (Note
10) is added to the concentrate in a
250-ml. flask. The rotary evaporation is continued until the weight remains constant and a free-flowing consistency is attained. The material is placed on a column packed with
800 g. of alumina and eluted with low-boiling
petroleum ether (Note
11). Fractions of
ca. 200 ml. are collected and analyzed by GC or TLC ((Note
6)), with the appropriate fractions combined and evaporated, providing
16.9–17.5 g. (
58–60%, (Note
12)) of essentially pure
tetrachlorobenzobarrelene, m.p.
127–129° (Note
13).
B.
Benzobarrelene. A
dry, 1-l., three-necked, round-bottomed flask equipped with a magnetic stirring bar, a combined gas-inlet tube and rubber septum, a 500-ml., pressure-equalizing dropping funnel, and a reflux condenser connected to a Nujol bubbler is charged with
500 ml. of dry tetrahydrofuran (Note
14) and
17 g. (0.74 mole) of sodium wire having a diameter of ca. 0.5 mm. The mixture is stirred and heated at reflux under an atmosphere of
argon or
nitrogen while
50 ml. of freshly distilled tert-butyl alcohol is added. Immediately afterward a solution of
15 g. (0.051 mole) of tetrachlorobenzobarrelene in
200 ml. of tetrahydrofuran is added over a 15-minute period. After 4 hours under reflux (Note
15) the contents of the flask are cooled to room temperature and filtered through a plug of glass wool (Note
16) into a
2-l. beaker containing
50 ml. of methanol. After any remaining pieces of
sodium have reacted with the
methanol, 400 ml. of water is added, and the mixture is extracted with six
150-ml. portions of ether. The combined
ether layers are washed with two
200-ml. portions of aqueous saturated sodium chloride, dried over
magnesium sulfate, and evaporated with a rotary evaporator operated at
water aspirator pressure and room temperature. The semicrystalline residue (7.3–8.1 g.) is mixed with
40 g. of alumina (Note
10) and swirled at room temperature under reduced pressure until it attains a free-flowing consistency. The material is then placed on a column packed with
600 g. of alumina and eluted with low-boiling
petroleum ether (Note
11). Fractions of
ca. 200 ml. are collected, evaporated, and assayed by GC (Note
15) and (Note
17). Combination of the appropriate fractions yields
5.9–6.8 g. (
75–86%) of benzobarrelene, m.p.
62–64.5° (Note
18).
2. Notes
1. The dropping funnel must be arranged so that the drops fall directly into the solution and not onto the side of the flask. The checkers used a
4-l., four-necked flask equipped with a mechanical stirrer and a ground-glass stirring assembly, and carried out the reaction on four-fifths scale.
2.
Technical-grade hexachlorobenzene was purchased by the submitters from BDH Chemicals, Ltd., and recrystallized twice from
benzene: m.p.
227°. The submitters found that if the technical-grade material is used without purification, some insoluble material remains after the reaction with
n-butyllithium, though the yield of
tetrachlorobenzobarrelene is only slightly reduced. The checkers used
22.8 g. (0.0800 mole) of hexachlorobenzene of 98% purity, purchased as a fine powder from EGA-Chemie K. G., an affiliate of Aldrich Chemical Company, Inc., without further purification.
3. The flushing operation was accomplished by replacing the bubbler with a stop-cock and alternately evacuating and filling the apparatus with inert gas three times. A slight outflow of inert gas should be maintained during all subsequent operations. When the flask is being cooled, it is necessary to increase the gas flow.
4.
Dry ether and dry, thiophene-free
benzene were prepared by the submitters according to procedures presented in reference
2.
5.
n-Butyllithium as 1.5–3.0 M solutions in hexane is available from the following firms: Pfizer, Ltd., Sandwich, England; Metallgesellschaft, Frankfurt, Germany; Alfa Division, Ventron Corporation. The appropriate volume of the solution is transferred with a
50-ml. syringe to the dropping funnel with care being taken to exclude air. An excess of
n-butyllithium above the 10% recommended here may lead to the formation of
dilithiotetrachlorobenzene.
6. The reaction of
n-butyllithium and
hexachlorobenzene and, later, the formation of tetrachlorobenzobarrelene may be monitored by GC or TLC. Samples withdrawn from the reaction mixture with a syringe are injected into a small amount of water, and the organic layer is analyzed. GC was carried out by the submitters with flame ionization detection and
1.5 m. × 4 mm. (inside diameter) glass column packed with 3% silicone rubber (SE-30) supported on 80–100 mesh Gaschrom Q. With a column temperature of 150° and a
nitrogen carrier gas flow rate of 45 ml. per minute, the retention times of
pentachlorobenzene,
hexachlorobenzene, and
tetrachlorobenzobarrelene are
ca. 2, 4, and 18 minutes, respectively. Normally trace amounts of
hexachlorobenzene are still detectable at the end of the reaction with
n-butyllithium. TLC was performed on silica gel with 5% ether in
pentane as developing solvent. The
Rf value of
tetrachlorobenzobarrelene is less than that of chlorobenzenes.
7. A clear yellow solution is usually obtained at this stage; however, some suspended material may be present, particularly when
technical grade hexachlorobenzene is used.
8. For proper temperature control the
cooling bath should be free from excess amounts of dry ice. The
benzene should be added in the following manner (volume of
benzene added, period of addition, final temperature reached): 0.5 l., 15 minutes,
ca. −20°; 0.5 l., 15 minutes,
ca. −10°; 3.0 l., 30 minutes,
ca. +10°.
9. The reaction is relatively slow at a laboratory temperature of 18–20° and may require as much as 40 hours to reach completion.
10. The submitters used
Activity I (Brockmann) Camag alumina, which was purchased from Hopkins and Williams. The checkers used comparable material obtained from E. Merck, Darmstadt, Germany.
11.
Low-boiling petroleum ether (b.p. 30–50° or 40–60°) was distilled from
calcium chloride prior to use.
12. The submitters usually combined fractions 5–14 and obtained
18–19.5 g. (
62–67%) of
tetrachlorobenzobarrelene, m.p.
127–131°. The checkers, using a
3.5 cm. × 1 m. column for the chromatography, isolated
13.5–14 g. (
58–60%) of product from fractions 10–25.
13.
1H NMR (CDCl
3): δ (multiplicity, number of protons, assignment): 5.45 (m, 2H, bridgehead
H), 6.95 (m, 4H, vinyl
H). A melting point of
125° is reported in the literature.
3
15. An aliquot may be removed at this stage and analyzed by either GC or TLC to ensure that the reaction is complete.
Benzobarrelene has a retention time of
ca. 5 minutes under the conditions stated in (Note
6), but with a column temperature of 104°. The completion of the reaction is also indicated by a purple coloration of the precipitated
sodium chloride.
17. The dimensions of the column used by the checkers were the same as those specified in (Note
12), and the product was obtained from fractions 10–20. The submitters evaporated the fractions with a rotary evaporator operated at water aspirator pressure and room temperature (
ca. 20°); however, the checkers caution that the product sublimes very readily.
18. IR cm.
−1, strong peaks: 1460, 1325, 790, 750, 690, 660;
1H NMR (CDCl
3): δ (multiplicity, number of protons, assignment): 4.9 (m, 2H, bridgehead
H), 6.8–7.3 (m, 8H, aryl and vinyl
H). The reported melting point is
65.5–66°.
4 From
20 g. of tetrachlorobenzobarrelene the submitters obtained
8.3–8.8 g. (
79–83%) of
benzobarrelene, m.p.
64–65°.
3. Discussion
Although
benzobarrelene has been used in a number of recent studies, the best available published synthesis
4 starts with the Diels-Alder reaction of
β-naphthol and
maleic anhydride, affording
benzobarrelene in
ca. 1% yield after five additional steps. Minor improvements allow small quantities of
benzobarrelene to be prepared in an overall yield of
ca. 10%.
5 The reaction of
benzyne with
benzene is relatively inefficient, giving
benzobarrelene in
ca. 2% yield.
6 When
benzyne is generated by decomposition of
benzenediazonium-2-carboxylate at high dilution in
benzene, the yield of
benzobarrelene is raised to
14%.
7 The reactions of
benzyne with other aromatic substrates are equally inefficient.
The generation of
pentachlorophenyllithium by the reaction of
n-butyllithium with
hexachlorobenzene has been reported previously by Rausch, Tibbetts, and Gordon.
10 The present procedure for the preparation of
benzobarrelene is based on the submitters' previously published note.
11 By this method 10-g. quantities of benzobarrelene may be obtained in
ca. 3 working days without the use of large-scale apparatus. The generality of the procedure is shown by the examples given in Table I.
Copyright © 1921-2002, Organic Syntheses, Inc. All Rights Reserved