Org. Synth. 1948, 28, 83
DOI: 10.15227/orgsyn.028.0083
PHENANTHRENE-9-ALDEHYDE
[9-Phenanthrenecarboxaldehyde]
Submitted by Clinton A. Dornfeld and George H. Coleman
1.
Checked by Robert E. Carnahan and Homer Adkins.
1. Procedure
A dry
5-l. three-necked flask is provided with a
stirrer (Note 1), a
nitrogen inlet tube, a
500-ml. Pyrex separatory funnel, and a
large Allihn reflux condenser. To the upper end of the condenser are attached an outlet tube and a
1-l. separatory funnel. Both separatory funnels and the outlet tube are provided with
calcium chloride drying tubes. To the flask is added
50.3 g. (2.07 gram atoms) of magnesium turnings (Note 2).
Nitrogen gas, dried by bubbling through concentrated
sulfuric acid, is passed in to displace the air in the flask. The
nitrogen atmosphere is maintained until the hydrolysis of the Grignard addition product is completed.
Five hundred and fourteen grams (2 moles) of crude 9-bromophenanthrene (p. 134) (Note 3) is melted and poured into the Pyrex separatory funnel
(Note 4).
One liter of anhydrous ether (dried over
sodium wire) is placed in the upper separatory funnel. About
200 ml. of the ether and
10 ml. of the melted bromophenanthrene are allowed to run into the reaction flask. The reaction of the
bromophenanthrene with
magnesium is initiated by the addition of a few crystals of
iodine and
1 ml. of ethyl bromide; the reaction begins after the mixture is stirred for a few minutes without external heating. As the reaction proceeds, the
ether and the bromo compound are added at rates sufficient to maintain gentle refluxing. The relative rates of addition should be such that the two separatory funnels will be emptied at about the same time. After the additions are complete, but while the reaction is still in progress, the Grignard reagent begins to precipitate on the sides of the flask.
One liter of dry, thiophene-free benzene is added from the Pyrex separatory funnel at such a rate as to keep the Grignard reagent in solution. When refluxing due to the exothermic reaction stops, the mixture is heated at gentle reflux with stirring for 4 hours.
The mixture is allowed to cool until refluxing ceases, and 296.4 g. (2 moles) of ethyl orthoformate (Note 5) is added from the lower separatory funnel over a period of about 30 minutes. The mixture is then refluxed gently for 6 hours.
The reaction mixture is cooled with stirring in an ice bath, and 1 l. of cold 10% hydrochloric acid (Note 6) is added from the separatory funnel; the acid is added dropwise at first and more rapidly after the reaction subsides. The benzene-ether layer is separated from the aqueous layer and concentrated under reduced pressure in a 5-l. round-bottomed flask on a steam bath. One liter of 25% sulfuric acid is added to the residue, and the mixture. is refluxed gently for 12 hours.
The mixture is then cooled in an ice bath, the acid is decanted, and the residue is washed twice by decantation with water. The residue is dissolved in 1 l. of benzene in the same flask, and 1.5 l. of water and 1.2 kg. of sodium bisulfite are added. The flask is fitted with a stirrer, and the mixture is stirred vigorously overnight. The mixture is filtered through an 8-in. Büchner funnel, and the bisulfite addition product is washed on the funnel with 500 ml. of benzene.
The filter cake is broken up and returned to the same 5-l. flask. A saturated solution of sodium bicarbonate is added slowly (Note 7) with stirring until there is no further evidence of decomposition. The mixture is stirred for 2 hours longer. The solution is kept alkaline to litmus throughout by the addition of more sodium bicarbonate if necessary. The crude aldehyde is collected on an 8-in. Büchner funnel, washed with water, and allowed to dry as completely as possible. The product is dissolved in 1 l. of chloroform, the small aqueous layer is separated (Note 8), and the solution is dried with Drierite or another suitable drying agent.
A 250-ml. modified Claisen flask, equipped with a dropping funnel, a thermometer, a water-cooled condenser, and a receiver, is arranged for distillation. The chloroform solution is filtered into the dropping funnel, from which it is admitted to the flask slowly as the solvent is distilled (Note 9). When the solvent has been removed, the dropping funnel is replaced by a stopper and the condenser by a 250-ml. distilling flask as a receiver. The residue is distilled at 160–170°/1 mm. The distillate weighs 206–216 g. (50–52%). This material is recrystallized once from glacial acetic acid (approximately 1 g. to 0.9 ml.) and then from ethanol (about 1 g. to 3 ml.) to give 166–174 g. (40–42% over-all yield) of phenanthrene-9-aldehyde melting at 100–101°.
2. Notes
1.
A
mercury seal may be used, but a
glycerol-rubber tube seal is adequate.
2.
The checkers operated on one-fifth the scale specified.
3.
Crude
bromophenanthrene prepared by the bromination of technical
(90%) phenanthrene and purified by distillation only was used by the submitters in this preparation. The
anthracene-9-aldehyde, which may be formed from the
anthracene present as an impurity in "90% phenanthrene," does not form a
sodium bisulfite addition product and so will not contaminate the
phenanthrene-9-aldehyde. The checkers used
9-bromophenanthrene, m.p.
54–56° (p. 134), exclusively, but without any advantage in yield. The submitters report yields of
55–60% from pure
9-bromophenanthrene.
4.
It is not feasible to add the
9-bromophenanthrene as an
ether solution because of the limited solubility of the substance in this solvent. Since the melting point of the crude
9-bromophenanthrene is about 50° it is desirable to heat the melted material to 70° in order to prevent crystallization in the funnel. If the bromo compound begins to solidify in the funnel it may be melted again by careful heating with a
microburner.
5.
The
ethyl orthoformate should be freshly distilled with rejection of the fraction boiling below 140°.
6.
If this procedure is used for the preparation of the acetal instead of the aldehyde, it may be preferable to use
ammonium chloride solution for hydrolysis instead of
10% hydrochloric acid.
7.
The alkaline solution must be added carefully to avoid excessive foaming.
8.
The water in the filter cake is removed with difficulty by drying in air or even in an
oven under reduced pressure. If the water is not removed as indicated in the procedure, difficulty may be encountered in the early part of the distillation.
9.
The distillation of the solvent may be carried out at reduced pressure if desired.
3. Discussion
Phenanthrene-9-aldehyde has been obtained by the Sonn and Müller synthesis from
9-phenanthroyl chloride,
2 by the Rosenmund reduction of
9-phenanthroyl chloride,
3 by the Gattermann hydrogen cyanide synthesis from
phenanthrene,
4 and by the reaction of
9-phenanthrylmagnesium bromide with
ethyl formate.
5 The procedure described above is an adaptation of the method of Miller and Bachman.
6 This Grignard method has also been used by others.
7
Appendix
Chemical Abstracts Nomenclature (Collective Index Number);
(Registry Number)
ethanol (64-17-5)
sulfuric acid (7664-93-9)
hydrochloric acid (7647-01-0)
acetic acid (64-19-7)
Benzene (71-43-2)
ether (60-29-7)
ammonium chloride (12125-02-9)
chloroform (67-66-3)
sodium bicarbonate (144-55-8)
magnesium,
magnesium turnings (7439-95-4)
Ethyl bromide (74-96-4)
nitrogen (7727-37-9)
sodium bisulfite (7631-90-5)
iodine (7553-56-2)
sodium (13966-32-0)
anthracene (120-12-7)
Ethyl orthoformate
ethyl formate (109-94-4)
phenanthrene (85-01-8)
9-phenanthrylmagnesium bromide
anthracene-9-aldehyde (642-31-9)
9-Bromophenanthrene (573-17-1)
bromophenanthrene
Phenanthrene-9-aldehyde,
9-Phenanthrenecarboxaldehyde (4707-71-5)
9-phenanthroyl chloride
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