Organic Syntheses, CV 6, 451
Submitted by Joseph F. Bunnett
1 and Robert H. Weiss.
Checked by S. C. Busman and O. L. Chapman.
1. Procedure
Caution!
Benzene has been identified as a carcinogen; OSHA has issued emergency standards on its use. All procedures involving
benzene should be carried out in a
well-ventilated hood, and glove protection is required.
A
2-l., three-necked, round-bottomed flask is fitted with an
ammonia condenser (Note
1) with an
outlet protected with a soda–lime drying tube, a
dropping funnel, a
nitrogen inlet, and a
magnetic stirrer. As a slow stream of
nitrogen is passed through the system, the condenser is charged with dry ice and
2-propanol, the funnel is briefly removed, about a liter of liquid
ammonia is added straight from a commercial
cylinder (Note
2), and the funnel is replaced. Bright, freshly-pared
sodium metal (11.8 g., 0.513 g.-atom) is added, turning the mixture blue.
Diethyl phosphonate (70.4 g., 0.510 mole) (Note
3) is cautiously added dropwise to the
sodium in
ammonia in the manner of a titration; the endpoint is the change from blue to colorless (Note
4).
Iodobenzene (52.4 g., 0.257 mole) (Note
5) is slowly added, giving the solution a slight yellowish tint (Note
6). The dropping funnel is replaced by a stopper, the frost is wiped off the outside of the flask with a towel dampened with
acetone, and the whole system is mounted in a
photochemical reactor of adequate design (Note
7).
Caution! The lamps must be shielded to prevent exposure of the eyes or skin to ultraviolet radiation. The flask is irradiated for 1 hour (Note
8), but every 20 minutes the lamps are shut off briefly while the exterior of the flask is freed of frost by spraying it, still mounted in the reactor, with
2-propanol from a
wash bottle.
After irradiation, the flask is removed from the reactor, and about
50 g. (0.62 mole) of solid ammonium nitrate is added with stirring to acidify the mixture. About
200 ml. of diethyl ether is added,
nitrogen flow is stopped, the condenser is removed, and the open flask is placed on a cork ring in an operating hood and allowed to stand overnight while the
ammonia evaporates. The next day 300 ml. of water (Note
9) and
300 ml. of ether are added, the
ether layer is separated, the water layer is extracted twice with
ether, and the combined
ether extracts are dried over anhydrous
sodium sulfate. After evaporation of the
ethyl ether, the residue is distilled under reduced pressure through a
short Vigreux column. After a small forerun,
50.3–56.1 g. (
90.4–92.5%) of
diethyl phenylphosphonate (Note
10) is collected at
73–74° (0.020 mm.) (Note
11).
2. Notes
1. An ammonia condenser is an enlarged cold finger design. The interior of the "finger" is a
reservoir for dry ice and
2-propanol.
2. When
ammonia distilled from
sodium metal is used, the yield is 3–5% greater, but use of
ammonia straight from the tank is recommended because of the greater convenience.
3. Commercial
diethyl phosphonate, formerly known as diethyl phosphite, was purchased from Aldrich Chemical Co., Inc. and used without further purification.
4. Some white foam forms as the
diethyl phosphonate is added. Because water in the
ammonia consumes some of the
sodium, not quite all the
diethyl phosphonate is required to reach the endpoint. Excess
diethyl phosphonate is deleterious.
6. When distilled
ammonia is used, this yellow coloration vanishes as the reaction occurs.
7. The submitters used a
Rayonet Model RPR-100 Photochemical Reactor, manufactured by the Southern New England Ultraviolet Company, Hamden, Connecticut 06514, equipped with 16 Cat. No. RPR-3500A fluorescent lamps (
ca. 24 W. each), rated to emit maximally at 350 nm. Equally good results were obtained with lamps rated to emit maximally at 300nm. For reactions on a 0.05-mole scale excellent yields were obtained, without using the commercial photochemical reactor, by irradiating for 1 hour with
two circular kitchen-type fluorescent lamps mounted on either side of the flask so as to partially encircle it.
8. The yield was not significantly improved by irradiating for 2 hours.
10. Spectral characterization is as follows: IR (neat) cm
−1: 1440 (P-C aryl), 1250 (P=O), 1020 (POC
2H
5), and 3060 (H-C aryl);
1H NMR (CDCl
3), δ (multiplicity, coupling constant
J in Hz., assignment): 1.3 (t,
J = 7, C
H3), 4.13 (quintet,
J = 7, C
H2), 7.33–8.06 (m, C
6H5).
11. The submitters obtained a yield of
46 g. (
83%), b.p.
90–92° (0.1 mm.).
3. Discussion
The procedure reported here is based on a reaction discovered by Bunnett and Creary,
2 and was first employed for preparative purposes by Bunnett and Traber.
3 It is attractive because of the high yield, the ease of work-up, and the cleanliness of the reaction. The reaction is believed to occur by the S
RN1 mechanism, which involves radical and radical anion intermediates.
2,4 The S
RN1 arylation of other nucleophiles, especially ketone enolate ions,
5 ester enolate ions,
6 picolyl anions,
7 and arenethiolate ions,
8 has potential application in synthesis.
This procedure has been utilized successfully with a variety of aryl iodides, but aryl bromides are much less reactive.
m- and p-Diiodobenzene,
m- and p-bromoiodobenzene, and
p-chloroiodobenzene give the corresponding phenylenediphosphonate esters.
2,3 o-Haloiodobenzenes undergo a dark reaction leading to deiodination and other products, but the S
RN1 reaction affording phosphate esters may be made to predominate if irradiation is started quickly.
9
The esters of arylphosphonic acids are cleaved to the acids by
hydrochloric, hydrobromic, or hydroiodic acid.
10 Arylphosphonic dichlorides (ArPOCl
2) are easily converted to esters by reaction with the alcohol in
pyridine solution.
11
Other methods for synthesis of arylphosphonic acids or their derivatives fall into four main categories. First, many aromatic compounds react with
phosphorus trichloride under
aluminum trichloride catalysis, to form aryldichlorophosphines (ArPCl
2).
12,13 These add
chlorine to form aryltetrachlorophosphoranes (ArPCl
4),
14,13 which may be hydrolyzed to arylphosphonic dichlorides or arylphosphonic acids. This sequence may be employed for preparations on a large scale, but is subject to the orienting effects of substituents when applied to substituted benzenes.
Second, arylphosphonic acids may be prepared by the copper-catalyzed reactions of arenediazonium tetrafluoroborates with
phosphorus trichloride or tribromide. This method has found wide use.
15
Fourth, the present procedure bears a resemblance to the photochemical reaction of aryl iodides with trialkyl phosphites, with which several dialkyl arylphosphonates have been prepared.
17 However, prolonged irradiation (>24 hours) in quartz vessels was employed.
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