Organic Syntheses, CV 5, 941
Submitted by J. I. G. Cadogan and R. K. Mackie
1.
Checked by William G. Dauben, Harold B. Morris, and Kent E. Opheim.
1. Procedure
A.
o-Nitrobenzalaniline. A mixture of
14 g. (0.15 mole) of aniline (Note
1) and
22.7 g. (0.15 mole) of o-nitrobenzaldehyde (Note
2) is heated in a
100-ml. round-bottomed flask on a
water bath for 1 hour, allowed to cool, and dissolved in
100 ml. of ether. The ethereal solution is dried, and the
ether is removed by distillation. The residue solidifies on standing (Note
3) and is recrystallized from
55 ml. of water-ethanol (1:8) to yield
29.4–31.8 g. (
87–94%) of yellow
o-nitrobenzalaniline, m.p.
64–66° (Note
4).
B.
2-Phenylindazole. In a
200-ml. round-bottomed flask fitted with a
condenser are mixed
50 g. (0.30 mole) of triethyl phosphite (Note
5) and
22.6 g. (0.10 mole) of o-nitrobenzalaniline. The apparatus is sealed from the atmosphere by means of a liquid paraffin bubbler that consists of a U-tube the bend of which is just filled with mineral oil. The apparatus is flushed with
nitrogen, and the contents are kept under
nitrogen during the reaction. The mixture is heated at 150° in an
oil bath for 8 hours and cooled, and the condenser is replaced by a Claisen distillation head.
Triethyl phosphite, b.p.
46–48° (10 mm.), and
triethyl phosphate, b.p.
90–92° (10 mm.), are removed by distillation under reduced pressure; the volume of distillate is 48–50 ml. On cooling, the black residue solidifies. The flask is filled with glass wool, and the remaining phosphite and phosphate (1–3 g.) are removed by distillation at 30–50° (1 mm.). The residue of crude
2-phenylindazole is distilled at
10−4 mm.; b.p.
108–112°. The yield is
13–15 g. (
67–78%) (Note
6) and (Note
7).
This product is crystallized from
75–100 ml. of ethanol-water (7:3) to yield pale yellow crystals, m.p.
81–82°. Additional material is obtained by dilution of the mother liquor with
ca. 200 ml. of water and two crystallizations as before. The total yield is
10–12 g. (
52–62%).
2. Notes
2. The reagent as supplied by British Drug Houses or Eastman Organic Chemicals was used directly.
3. If the product does not solidify at room temperature, it should be cooled with dry ice.
4.
o-Nitrobenzalaniline is very photosensitive and should be kept away from light as much as possible.
5. The reagent as supplied by Albright and Wilson, Ltd., or Matheson, Coleman and Bell was fractionally distilled from
sodium and used within a few days of distillation.
6. A slightly purer sample may be obtained by chromatography on
alumina. Elution with
chloroform-benzene (1:4) gives a pale yellow solid which is purified further by crystallization from
70% ethanol.
7. The checkers found it more convenient to transfer the crude, black
2-phenylindazole to an apparatus for simple bulb-to-bulb distillation and not to retain the distillation head.
3. Discussion
The procedure given here is essentially that described previously by the submitters
2 and is based on the early work of Knoevenagel.
3 2-Phenylindazole has been prepared by reduction of
N-(o-nitrobenzyl)aniline with
tin and
hydrochloric acid,
4 by reduction of
N-(o-nitrobenzyl)-N-nitrosoaniline with
tin and
hydrochloric acid,
5 by dehydration of
2-(phenylazo)benzyl alcohol,
6 by elimination of
acetic acid from
2-(phenylazo)benzyl acetate,
7 by dehydrogenation of
3,3a,4,5,6,7-hexahydro-2-phenylindazole with
sulfur,
8 and by thermal decomposition of
o-azidobenzalaniline.
9
4. Merits of the Preparation
Reductive cyclization of nitro compounds by
triethyl phosphite is a general method for the preparation of a variety of nitrogen-containing heterocyclic systems. The submitters have synthesized the following ring systems by this method from the starting materials given in parentheses: 2-arylindoles (
o-nitrostilbenes),
2 2-arylindazoles (
o-nitrobenzalanilines),
2 2-arylbenzotriazoles (
o-nitroazobenzenes),
2 carbazoles (
o-nitrobiphenyls),
2 phenothiazines (
o-nitrodiphenyl sulfides),
10,11 and anthranils (
o-nitrophenyl ketones).
10
The products are isolated in good yield in a one-stage synthesis from starting materials that are readily available in the main. An alternative method involves the decomposition of the corresponding azides.
9,12 These compounds are less readily available and are more hazardous to use than are the nitro compounds used in the present synthesis. This synthesis also gives better yields than the cyclization using
ferrous oxalate,
12,13 which is performed under much harsher conditions. The present method of synthesis has been reviewed.
14
Copyright © 1921-2002, Organic Syntheses, Inc. All Rights Reserved