In a
5-l. round-bottomed flask are placed
165 g. (1 mole) of ethyl p-aminobenzoate (Note
1), 300 cc. of water, and
204 cc. (2.5 moles) of concentrated hydrochloric acid (sp. gr. 1.19). This mixture is warmed on a
steam bath for an hour with occasional shaking. The flask containing the resulting white paste of
p-carbethoxyaniline hydrochloride is placed in an
ice-salt bath and cooled to 0°. The mixture is stirred mechanically, and a solution of
72.6 g. (1 mole) of 95 per cent sodium nitrite in a minimum quantity of water is run in slowly while the temperature is kept below 7°. The diazotization is complete when a faint positive test for
nitrous acid with starch-iodide paper persists for ten minutes.
While the diazotization is in process,
68 g. (1.1 moles) of boric acid is dissolved in
133 g. (4 moles) of 60 per cent hydrofluoric acid (Note
2) in a
beaker coated with paraffin-wax. The temperature is kept below 25° during the addition to avoid melting the paraffin-wax, and, after the addition, the solution is chilled in an
ice-water bath.
The ice-cold
fluoboric acid solution is added rather rapidly, with stirring, to the diazonium solution while the temperature is kept below 10°. A thick paste of
p-carbethoxybenzenediazonium fluoborate precipitates; stirring is continued for twenty to thirty minutes. The solid is filtered on an
18.5-cm. Büchner funnel and washed consecutively with 300 cc. of cold water,
300 cc. of commercial methyl alcohol, and
200 cc. of commercial ether; it is sucked as dry as possible between washings. The fluoborate is then dried over concentrated
sulfuric acid (sp. gr. 1.84) in a
vacuum desiccator (Note
3). The yield of the dried fluoborate is
198–205 g. (
75–78 per cent of the theoretical amount); the decomposition point is
93–94°.
The thermal decomposition may be conveniently carried out in a
2-l. distilling flask. A second distilling flask of 1-l. capacity is connected directly to the side arm of the first to serve as a
receiver. Attached to the side arm of the receiver is a rubber tube arranged to lead the escaping gases over 2 l. of water in a
5-l. round-bottomed flask. The
boron trifluoride dissolves in the water, and the other gases are led into a good
hood (Note
4). The
p-carbethoxybenzenediazonium fluoborate is placed in the decomposition flask and heated at its upper edge with a Bunsen flame. When the white fumes of
boron trifluoride commence to appear, the flame is removed and the decomposition is permitted to proceed spontaneously. The heat is applied as necessary, and finally the flask is strongly heated to complete the decomposition and melt the solid. Some of the ethyl ester, b.p. 105–106°/25 mm., of
p-fluorobenzoic acid is collected in the receiver, where it is carried by the gases, but the larger part is left in the decomposition flask. The ester is washed from the decomposition flask and the receiver with
ether, and the ether is distilled from a steam bath. The residue is refluxed for one hour on a steam bath with a solution of
56 g. (1 mole) of potassium hydroxide in
80 cc. of 95 per cent ethyl alcohol and 120 cc. of water. The solution is then filtered while still hot. The
p-fluorobenzoic acid is precipitated by adding concentrated
hydrochloric acid to the hot filtrate until the mixture is acid to Congo paper. After the mixture has cooled, the solid is filtered and allowed to dry. For purification, the
p-fluorobenzoic acid is dissolved in a hot solution of
40 g. of potassium carbonate in 400 cc. of water; the solution is treated with
Norite and filtered hot.
Hydrochloric acid is added with stirring to precipitate the
fluorobenzoic acid, which is then cooled, filtered, and dried.