Organic Syntheses, CV 7, 424
Submitted by M. T. Reetz, I. Chatziiosifidis, F. Hübner, and H. Heimbach
1.
Checked by Kevin Kunnen and Carl R. Johnson.
1. Procedure
A.
1-Trimethylsiloxycyclopentene.
2 A
1-L, two-necked, round-bottomed flask is equipped with a
mechanical stirrer and a
reflux condenser having a
drying tube (calcium chloride). The flask is charged with
200 mL of dimethylformamide (Note
1),
45 g (0.54 mol) of cyclopentanone (Note
2),
65.5 g (0.6 mol) of chlorotrimethylsilane (Note
2), and
185 mL (1.33 mol) of triethylamine (Note
1), and the mixture is refluxed for 17 hr (Note
3). The mixture is cooled, diluted with
350 mL of pentane, and washed four times with
200-mL portions of cold saturated aqueous sodium hydrogen carbonate. The aqueous phases are extracted twice with
100-mL portions of pentane and the combined organic phases are washed rapidly with
100 mL of ice–cold aqueous 2 N HCl and immediately thereafter with a cold saturated solution of
sodium hydrogen carbonate. After the mixture has been dried over anhydrous
magnesium sulfate, the
pentane is removed by rotary evaporation. Distillation of the oily residue at
60°C (12 mm) using a
20-cm Vigreux column affords
50.1–51.6 g (
60–62%) of
1-trimethylsiloxycyclopentene (
1) as a colorless liquid (Note
4).
B.
2-tert-Pentylcyclopentanone. A dry,
250-mL, three-necked, round-bottomed flask is fitted with a
gas inlet, a
gas bubbler,
rubber septum, and
magnetic stirrer. The apparatus is flushed with dry
nitrogen or
argon and charged with
120 mL of dry dichloromethane (Note
5),
15.6 g (0.10 mol) of 1-trimethylsiloxycyclopentene and
11.7 g (0.11 mol) of 2-chloro-2-methylbutane (Note
6). The mixture is cooled to −50°C (Note
7) and a cold (−50°C) solution of
11 mL (0.10 mol) of titanium tetrachloride (Note
8) in
20 mL of dichloromethane is added within 2 min through the rubber septum with the aid of a syringe. During this operation rapid stirring and cooling in maintained. Sunlight should be avoided. The reddish-brown mixture is stirred at the given temperature for an additional 2.5 hr and is then rapidly poured into 1 L of ice–water (Note
9). After the addition of
400 mL of dichloromethane, the mixture is vigorously shaken in a
separatory funnel; the organic phase is separated and washed twice with 400-mL portions of water. The aqueous phase of the latter two washings is extracted with
200 mL of dichloromethane; the organic phases are combined and dried over anhydrous
sodium sulfate. The mixture is concentrated using a
rotary evaporator and the residue is distilled at
80°C (12 mm) (Note
10) to yield
9.2–9.5 g (
60–62%) (Note
11) of
2-tert-pentylcyclopentanone as a colorless oil (Note
12).
2. Notes
3. According to the original procedure of House,
2 only 4 hr is needed, affording a 59% yield. However, the submitters found that an increase in reaction time raises the yield.
4. The spectral properties of the compound are as follows:
1H NMR (CCl
4) δ: 0.2 (s, 9 H), 1.6–2.4 (m, 6 H), 4.4 (m, 1 H); IR (film) 1645 cm
−1 (lit.
2 1645 cm
−1).
5.
Reagent-grade dichloromethane is dried by passing over a
column of aluminum oxide (activity I).
6. The submitters purchased
2-chloro-2-methylbutane from Eastman Kodak Company. The checkers prepared the halide as follows. A separatory funnel was charged with
21.5 mL (0.2 mol) of 2-methyl-2-butanol and
100 mL of concentrated hydrochloric acid. The mixture was shaken vigorously with periodic venting for 10 min. The layers were separated and the
2-chloro-2-methylbutane layer (upper) was washed several times with equal volumes of cold water. The product was dried over
calcium chloride and distilled, bp
85°C.
7. The precise temperature is not critical. The checkers observed that the reaction proceeds in about the same time and yield at −78°C. However, at temperatures above −40°C a drop in yield may occur.
9. If
sodium bicarbonate is used, large amounts of titanium oxide-containing emulsions tend to form that hamper the purification of the product.
10. The by-products consist of volatile
cyclopentanone and an unknown high-boiling material, so that rapid vacuum transfer at room temperature and 0.02 mm is also possible. Extremely slow distillation at high temperatures should be avoided. The value of 72°C (2.2 mm) cited in the literature
3 seems to be in slight error.
11. The submitters ran the reaction on a 0.5 scale and reported yields of
63–68%.
12. The product is >96% pure as checked by gas chromatography (4% UCON LB 550X, Chromasorb G, AW-DMCS 80–100 mesh, 130°C). The spectral properties are as follows: IR (neat) cm
−1: 3050–2800, 1735, 1460, 1150;
1H NMR (CCl
4) δ: 0.80 (
J = 6 Hz, CH
3 of the ethyl group, which partially overlaps with the signals of the other two diastereotopic methyl groups), 0.82 (s), 0.92 (s), 1.15–2.25 (m);
13C NMR (CDCl
3) δ: 7.78, 19.87, 23.72 (slightly broad), 25.57, 32.62, 34.70, 40.02, 55.39, 219.57.
3. Discussion
This procedure solves the long-pending problem of α-
tert-alkylation of ketones. The generality is shown by the fact that a wide variety of structurally different ketones can be alkylated via the corresponding silyl enol ethers with good yields.
4 Variation of the alkylating agent is also possible, branched and cyclic tertiary alkyl halides reacting position specifically without signs of rearrangement.
4 Chemoselectivity studies reveal that esters, aromatic groups, and primary alkyl halide moieties are tolerated.
4 In the case of a sensitive enol ether such as that derived from
acetone,
titanium tetrachloride should be replaced by more mild Lewis acids such as
zinc chloride, although the yields are lower.
5 Finally, it should be noted that any S
Nl-reactive alkyl halide is likely to be a suitable alkylating agent in Lewis acid-promoted α-alkylation of carbonyl compounds. Indeed, aryl-activated secondary alkyl halides and acetates react in the same way.
6 Heteroatom substituted alkyl halides and acetates also react smoothly with enol silanes in the presence of ZnX
2.
4,6 Generally, such alkylating agents are unsuitable in classical enolate chemistry because of the ease of hydrogen halide elimination and/or the failure to react regiospecifically. The methods are thus complementary.
A number of alternative multistep procedures for the synthesis of α-
tert-alkyl ketones are known, none of which possess wide generality. A previous synthesis of
2-tert-pentylcyclopentanone involved reaction of
N-1-cyclopentenylpyrrolidine with
3-chloro-3-methyl-1-butyne and reduction of the resulting
acetylene (overall yield
46%).
3 However, all other enamines tested afford much lower yields.
3 Cuprate addition to unsaturated ketones may be useful in certain cases.
9 Other indirect methods have been briefly reviewed.
5
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