938 table i - ACS Publications

4,5,6,7,7-HEXACHLORONORBORNENES. R and. R' and Yield,. Calcd. Found. Preparation. Position. Position Mole %. B.P.. M.P.. C. H. C1. C. H. C1. 1. 1Q. 2...
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938

VOL.

NOTES

26

TABLE I ~,4,5,6,7,7-HEXACHLORONORBORNENES

Preparation

R and Position

R' and Yield, Position Mole %

1

'

B.P.

M.P.

C

Calcd. H C1

95

180-185

0.8

-

43.1 2.6

-

42.6 2.6

-

49.2

- -

49.0

- 50.7

- -

50.8

-

47.1 3.7

-

-

45.8 47.4 48.0 48.0 44.0 46.1

4'

H

40

171-175* 0.3

-

- -

2

4'

H

77

165-170'

0.2

-

-

2

-

CH3

88

175-180

0.3

-

H H CHs CH3 H CH3

74

153-156 173-175 185-188

0.2 0.1 0.5

4345

3' 3'

3'

Found H C1

H

1Q

3 3 3 3 3 3

C

76 74 80 69 35

-

-

210-212d 0.5 19&203 0.4

-

98-100 154-155 -

70-72

47.2 3.7 45.8 47.2 48.4 48.4 44.3 45.5

3.4 3.7 4.0 4.0 3.2 3.6

49.0 47.6 47.6

-

47.4

3.7 3.9 3.9 4.2 3.2 3.8

-

48.5 47.3 47.4

-

46.5

I n this example, R " is CHI; in all other cases, R" is H. Mol. wt.: calcd.: 432;found: 415 f 12. Mol. wt.: calcd.: 418; found: 413 f 12. Mol. wt.: calcd.: 434;found: 444 f 13.

is stable to many chemical reactions, especially Compounds Derived from Sodium 1 oxidation. However, its size limits alkylation with p-Formyl-P-keto-a-nitropropionate isopropenylhexachloroiiorbornene to the preparation of m- and p-substituted aromatics. Phenol and PAULE. FANTA, R. M. W. RICKETT, AND DANIELS. JAMES where the alkylating group would be forced to enter ortho to a ring substituent, did not alkylate Received June 85, 1960 a t all. Failure of isopropenylhexachloronorbornene to The formation of aldoximes by the pyrolysis of alkylate p-disubstituted benzenes indicates that nitronic esters (conveniently obtained from the the structures assigned to the products from o- treatment of primary aliphatic nitro compounds and m-xylene and o-cresol in Table I are correct. with diazomethane) was reported by Arndt and The structures are confirmed by infrared absorp- Rose.2 & part of our study of compounds derived tion data. The major product from isopropenyl- from sodium P-formyl-0-keto-a-nitropropionate hexachloronorbornene and o-xylene shows char- (I),3 two nitro compounds readily obtained from acteristic absorption for 1,2,4-trisubstituted ben- compound I were subjected to this reaction. zenes in the 5-6 p region. The corresponding comTreatment of 2-nitromethylquinoxaline (IIa) pound from m-xylene shows typical absorption with diazomethane gave the nitronic ester (IIb): for a 1,3,5-trisubstituted benzene in the 5.5-6 p which was not isolated, but on sublimation a t region. Monosubstituted benzenes give mixtures of 120-140O gave the previously reported* quinoxaisomers. line-2-aldoxime (IIc). Isopropenylhexachloronorbornene,although similar in structure to isobutylene, would not polymerize with the strong Lewis acids, boron trifluoride, or aluminum chloride. With isobutylene IIa. R = CHZNOZ and boron trifluoride, it gave low-molecular-weight IIb. R = CH=NOZCHI IIc. R = CH=NOH products. Its inability to enter into cationic polymerizations is undoubtedly due to its bulk. The same series of reactions applied to nitroHexachloronorbornenes are useful as pesticides, pyruvaldehyde phenylosazone (111) gave l-phenylvulcanizing agents, and lubricant additive^.^^^ 4-benzeneazopyrazole (VI) in place of the expected The methods described make possible the ready (1) Supported by research grant CY-2240 from the synthesis of many new hexachloronorbornenes. '

RESEARCH AND DEVELOPMENT DEPARTMENT STANDARD OILCO. WHITING,IND. (5) E. K. Ficlds, J. A m . Chew SOC.,78, 5821 (1956).

National Cancer Institute of the National Institutes of Health, U. S. Public Health Service. (2) F. Arndt and J. D. Rose, J. Chem. SOC.,1 (1935). (3) P. E. Fanta, R. A. Stein, and R. M. W. Rickett, J. Am. Chem. SOC.,80, 4577 (1958)is the previous paper in this series.

MARCH

1961

939

NOTES

oxime (IV). Formation of VI may be rationalized ment of the sulfo group by hydrogena oxidation of as occurring via cyclization of the hydroxylamine side chainsJ4and decarboxylation5 are well known. attacked at all-are compound V (a tautomer of IV), with elimination Usually, alkyl groups-if of a molecule of hydroxylamine. This reaction is oxidized completely to carboxyl groups.6 We exactly analogous to the reported formation of VI have observed the conversion of an ethyl group by the acid-catalyzed elimination of phenylhy- into a methyl group in the alkali fusion of 4-ethyldrazine from mesoxaldehyde trisphenylhydra~one.~3,5-disulfobenzoic acid (I). This compound was prepared by the sulfonation of p-ethylbenzoic acid CHzNOz HC=NOH using a modification of the method of Asahina and I I Asano? and characterized through its p-toluidine C=NN HC& 1. CHzNz+ C=NNHCsH:, 2. heat I I salt, it sulfonyl chloride, and its sulfonamide. The HC=NNHCsHs HC=NNHCeH$ presence of the two sulfonic acid groups in the benI11 IV zene ring was confirmed by sealed-tube oxidation Jt with fuming nitric acid to 3,5disulfoterephthalic acid. C&5N--CH CeH,NH-CH-N HOH Fusion of the barium salt of I with potassium -NHrOH I 11 IN CN=NCeHj II hydroxide at 260-290' gavc a mixture from which N CN=NCeHs \C/ *C' hydroxyterephthalic acid, 4-ethyl-3-hydroxy benzoic H H acid, m-hydroxybenzoic acid, and 3-hydroxy-4VI v methylbenzoic acid (11) were isolated together with several small, unidentified fractions. No 4-ethylEXPERIMENTAL 3,5-dihydi-oxybenzoic acid was found. Compound Quino~aline-&aldozinze.2-Nitromethylquinoxalinea was I1 was obtained from a chromatographic separation added in portions to an ether solution containing a three- of the mixture resulting from the alkali fusion, fold excess of diazomethane and a little ethanol. After several hours the solution was filtered and the excess diazomethane using moist silicic acid as the fixed phase and and solvent were removed from the filtrate by distillation. eluting with butanol-hexane mixtures. I t was idenThe residue was sublimed a t 120-140"/0.5 mm., giving a tified by its neutralization equivalent, carbon-hydropale yellow solid, m.p. 189-199". Recrystallization of the gen analysis, and by a mixed melting point determicrude material from chloroform gave quinoxaline-2-aldoxime, nation. white solid, m.p. 202' (lit.,4 m.p. 197-198'). The formation of I1 could be accounted for by 1-Phenyl-$benzeneazopyrazole. Nitropyruvaldehyde phenylosazonea (2.96g., 9 mmolcs) was added in portions to 50 assuming that the oxidation of the ethyl group ocml. of an ether solution containing 22 rnmoles of diazo- curred in steps, leading first to 2-hydroxyhomomethane. Ethanol (75 ml.) was added until the osazone was terephthalic acid, which on side chain decarboxylaalmost completely dissolved. The reaction mixture was stirred for 1.5 hr., filtered, and the filtrate was distilled tion could yield 11, which could then be oxidized first at atmospheric pressure and then a t reduced pressure further to hydroxyterephthalic acid. This is in to remove solvent. The residue was sublimed a t 120-130°/ agreement with the observation that 2,6-dimeth0.1 mm. for 18 h r , giving a yellow-orange sublimate. oxyhomoterephthalic acid gives on decarboxylation Recrystallization of the crude material from ethanol gave 0.31 g. of yellow needles, m.p. 124.6-126.2', A?': 332 m# 3,5dimethoxy4-methylbenzoic acid as one of the A?': 335 m r principal products.8 (broad), log e 4.18 (lit,,S map. 124-125', (broad), log c 4.4). Anal. Calcd. for CxsHIIN,: C, 72.58; H, 4.87; N, 22.57. Found: C, 72.21;H, 5.09;N, 22.56. DEPARTMENT OF CHEMISTRY ILLINOIS INSTITUTE OF TECHNOLOW CHICAGO 16, ILL. (4) Von W. Borsche and W. Docller [Ann., 537, 39 (1939)] prepared IIc by treatment of the corresponding aldehyde with hydroxylamine. (5) C. F. Huebner and K. P. Link, J . Am. Chem. Soc., 7 2 , 4812 (1950).

Partial Side Chain Degradation in Alkali Fueion' JOH.4NN

c. F. SCHULZ' A N D P A U L M. RUOFF Received June 5'4, 1960

Among the side reactions that can occur in the alkali fusion of alkylbenzenesulfonic acids, replace-

EXPERIMENTAL

~-Ethy1-3,5-disulfobenzoicacid (I). A mixture of 45 g. (0.3 mole) of twice recrystallized p-ethylbenzoic acid (m.p. 111113') and 180 g. of 65% oleum was refluxed for 8 hr. a t (1) Abstracted from the dissertation submitted by Johann C. F. Schulz to the Graduate School of Syracuse University in partial fulfillment of the requirements for the degree of Doctor of Philosophy. (2) Present address, Department of Chemistry, Wagner College, Staten Island 1, N. Y. (3) 0. Jacobsen and H. Meyer, Be?., 16, 190 (1883); 0.Jacobsen, Ann., 206, 172 (1881); L. Barth and J. Herzig, Monatsh., 1 , 808 (1880). (4) C. M. Suter, The Organic Chemistry of Sulfur, John Wiley and Sons, Inc., New York (1944),p. 422. ( 5 ) C. Fahlberg, Am. Chem. J., 2 , 181 (1880);E. H. Charlesworth and R. Robinson, J. Chem. SOC.,1531 (1934). (6) 0.Jacobsen, Ann., 196, 282 (1879);J. Stahl, Ber., 23, 990 (1890);C. W. Rloinstrand and P. Hakansson, Ber., 5, 1084 (1872). (7) Y. Asahina and J. Anano, Ber.,,66B, 687 (1933). (8) F. E.King and M. F. Grundon, J. Chem. Soc., 3348 (1949).