Tautomeric Equilibria. VII. Substituent Effects in

June 5, 1964

SUBSTITUENT

EFFECTS I N DIMETHYLAMINOAZOBENZENES

Relative rates for chloro- and bromobenzene were also obtained from competition of chloro- and bromobenzene with fluorobenzene and that of chlorobenzene with bromobenzene. Determination of Isotope Effect.-(a) Benzene-& (0.025 mole) and toluene (0.025 mole) were dissolved in 5 g. of nitromethane and acetylated with 0.01 mole of CH3CO+Sb&- as previously described. The products were analyzed by gasliquid chromatography. ( b ) Benzene& (0.025 mole) and benzene (0.025 mole) were dissolved in 5 g. of nitromethane and acetylated with 0.01 mole of CHaCO+SbXG- as previously described. The products were analyzed by mass spectroscopy. ( c ) Benzene (0.025 mole) and toluene-& (0.025 mole) were dissolved in 5 g. of nitromethane and acetylated with 0.01 mole of CH3COfSbF6- as previously. The products were analyzed by gas-liquid Chromatography. ( d ) Benzene-& (0.025 mole) and toluene-& (0.025 mole) were dissolved in 5 g. of nitromethane and acetylated with 0.01 mole of CH&O+SbFs- as previously. T h e products were analyzed by gas-liquid chromatography. (e) Benzene (0.025 mole) and toluene-a,a,a-d3 (0.025 mole) were dissolved in 5 g. of nitromethane and acetylated with 0.01 mole of CH3cO+SbF6- as described in (a). The products were analyzed by gas-liquid chromatography. ( f ) Benzene (0.025 mole) and toluene-&, (0.025 mole) were acetylated as in (e). ( 9 ) Benzene (0.025 mole) and mesitylene-&, (0.025 mole) were acetylated as in ( e ) . Analytical Procedure.-Gas-liquid chromatography was carried o u t o n a Perkin-Elmer Model 154-C vapor fractometer, using a thermistor detector, equipped with a Perkin-Elmer Model 194 electronic printiiig integrator. A 4-m. X 0.25 in. stainless

[CONTRIBUTION FROM

THE

2209

steel column packed with polypropylene glycol (UCOK LB 550-X) supported on diatomaceous earth was used. The column temperature was 180" for all of the determinations; 25 ml. of hydrogen per minute was used for carrier gas. Relative response was determined by making up known solutions of acetophenone, alkylacetophenones, and haloacetophenones in excess benzene in the ratios approximating those occurring in the reaction mixtures and determining the response per mole relative to acetophenone as analyzed by gas-liquid chromatography. Characteristic retention times of acetophenone, alkylacetophenones, and haloacetophenones are given in Table X. TABLE X

RETENTION TIME(MISUTES) Acetophenone o-Methylacetophenone m-Methylacetophenone +-Methylacetophenone 2,5-Dimethylacetophenone 2,4-Dimethylacetophenone

13 16 20 21 23

4 0 6 6 25 6

3,4-DimethyIacetophenone 36 8 2,4,6-Trimethylacetophenone 30 4 0-Fluoroacetophenone 12 0-Chloroacetophenone 29 0-Bromoacetophenone 34

Acknowledgment.-Dr. L. B. Westover, Chemical Physics Research Laboratory, Dow Chemical Co., Midland, Mich., is thanked for the mass spectroscopic analyses, and Dr. J. S. McIntyre for the n.m.r. spectra obtained on a Varian Model A-60 spectrometer.

DEPARTMENT OF CHEMISTRY, UNIVERSITY

OF

CINCINNATI, CINCINNATI 21,

OHIO]

Tautomeric Equilibria. VII. Substituent Effects in Dimethylaminoazobenzenes BY M. ISAKSAND H. H.

JAFF~

RECEIVEDNOVEMBER 21, 1963 The effect of substitution on the tautomeric equilibrium in substituted dimethylaminoazobenzenes has been investigated. The tautomeric equilibrium constants for seven 4'-substituted-4-dimethylaminoazobenzenes have been obtained and have been found to follow the Hammett equation. The spectroscopic behavior of the first conjugate acid of dimethylaminoazobenzene and the comparability of Ho and H+ acidity scales were also investigated

The structures of the first conjugate acids of 4-dimethylaminoazobenzenes have been under much discussion. A number of workers have reached widely varying conclusions on this problem. More recently it has become clear that there is a tautomeric equilibrium between ammonium (I) and azonium (11) forms.3 With the exception of some semiquantitative work by the method of S a ~ i c k i the , ~ only careful attempt at determination of tautomeric equilibrium constants has been performed in this l a b o r a t ~ r y , ~and ' , j only on the parent compound. $%'e have now re-examined and improved this work, and extended it to a series of substituted derivatives. ( 1 ) Support of this work b y a research g r a n t from t h e American Cancer Society is gratefully acknowledged. (2) (a) A. Hantzsch and F. Hilsher, Be?., 41, 1171 (1908); (h) F.Kehrm a n n , i b i d . , 48, 1933 (1915); (c) .4 Hantzsch and A. Burawoy, i b i d . , 63, 1760 (1930); ( d ) XI. T. Rogers. T. W Campbell, and R . W. M a a t m a n , J . A m . Cheni. Soc., 73, 5122 (1951), (e) I. M. Klotz, H . A . Fiess, J. Y. Chen-Ho, and M. Mellody, i b i d . , 76, 5136 (1954) (3) (a) G . hZ. Badger, R . G B u t t e r y , and G . E . Lewis, J . Chfm. Soc., 1888 (1954); (b) E.Sau-icki and F.E . R a y , J . O v g , Chem., 1 9 , 1686 (1954); c) E.Sawicki, i b i d . , 21, 605 (1950); ( d ) ibid., 22,365,621,743 (1957); (e) G. Cilento, Cancer R e s . , 2 0 , 120 (1960), ( f ) A. Zenhausern and H. Zollinger, Helo. C h i m . A c l n , 46, 1842, 1890 (1962), (g) F. Gerson and E . Heilbronner, i b r d . , 46, 42 (1962); ( h ) I. Granacher, H. S u h r , A Zenhauserh, and H . Zollinger, ibid , 44,313 (1961); (i) H . H.Jaffk and S. J. Y e h , J . Oug. C h ~ m . , 22, 1281 (1057); ( j ) S.1. Yeh and H . H . Jaff6, J . A m . Chem. Soc., 81,3283 (1959); (k) G. E . Lewis, Telraheduon, 10, 129 (1960).

Experimental Dimethylaminoazobenzenes (4-DAB).-4'-Substituted-4-DAB were prepared by diazotization of the appropriate p-substituted aniline and coupling of the resulting diazonium salt with dimethylaniline in an acetate b ~ f f e r . The ~ products were recrystallized from ethanol to a constant melting point, in all cases equal to or greater than values reported in the literature (cf. Table I ) . Elemental analysis5 on these compounds checked very closely with theoretical values. Trimethylammonioazobenzene Chlorides. N , N ,N-Trimethylp-phenylazoanilinium Chloride (4-TAB).-The 4'-substituted dimethylaminoazobenzene ( 3 g.) was dissolved in C Q . 30 ml. of methyl iodide and heated under reflux for 2 to 4 days. The resulting precipitate of trimethylammonioazobenzene iodide was collected, washed with anhydrous ether, and dried. The precipitate was then dissolved in 1 ' 1 ethanol-water and passed through a 10-g. column of Dowex 2-X8 ion-exchange resin. The solvent was then removed under aspirator vacuum and the residue dissolved in absolute ethanol and precipitated by addition of anhydrous ether. The dissolving in ethanol then reprecipitating with ether steps were repeated a number of times. The product was then dissolved in 957, ethanol and passed once more through a 10-g. column of the same ion exchange resin. After removal of solvent, the reprecipitation was repeated once more. Finally the product was collected and dried in vacua. The yields were generally in the range of 607,. The purity of the compounds was checked by elemental analysis (cf. Table I ) . (4) "Organic Syntheses." Call. Vol. I , H . Gilman, E d . , John Wiley and Sons, Inc., New Y o r k , N.Y . , 1941,p . 347. ( 5 ) Elbmental analyses were performed by A. Bernhardt, Mulheim ( R u h r ) , Germany.

M. ISAKSAND H . H . JAFFB

2210

Vol. 86

TABLE I ACIDITIESAND MELTIXG POISTS

---

4'-Substituent

M . p . , 'C.

O F 4 ' - s U B S l ITUTED

4-DAB

A S D OF

SUBSTITUTED 4-TAB ~

DAB----pKma

M . p . , OC.

-Carbon, o/oCalcd. Found

Hydrogen, % -Nitrogen, %Calcd. Found Calcd. Found

Methoxy 164-165 2 . 7 4 i 0 . 0 1 185-186d. 62.84 6 3 . 2 8 6.59 6 57 13 74 1 3 . 6 1 Methyl 1 6 9 . 5 1 7 0 4 . 2 3 i .O1 178-179d. 66 31 66.56 6 . 9 6 7 . 3 8 14 50 1 3 . 8 9 Xone 119-120 5 . 3 4 1. .02 186-187d. 65 32 65 17 6 . 5 8 6 . 4 3 1 5 . 2 4 15.02 58.07 58.14 5 . 5 2 5.56 13.56 13.61 Chloro 158-159 5 . 6 1 f . 0 1 184-185d. Bromo 160-161 5 70 i . 0 1 187-188d:" 50.80 5 0 . 7 3 4 83 4 . 8 9 1 1 . 8 5 11 60 Trifluoromethyl 178-178.5* 7 . 1 0 i .02 179-180d.d 55.90 56.02 4 98 4 . 9 0 1 2 . 2 2 1 2 . 0 7 Sitro 230-231 8 . 3 4 f . 0 1 224-225d. 56.16 55.96 5 34 5 . 4 7 17 45 1 7 . 3 4 a 3z Standard deviation from the mean. * A n a l . Calcd.: C, 61.43; H, 4.18; N, 14.33. Found: Anal, Calcd.: Br, 22.53. Found: Br, 22.64. Anal. Calcd.: F, 16.58. Found: F, 16.56.

pK Measurements .-All pK. measurements were carried out using a standard spectrophotometric method6 with a Beckrnan DU quartz spectrophotometer. The HOacidity scale for 20y0 ethanol-sulfuric acid developed by JaffC and Gardner' and extended by Yeh and JaffC8 was used.

-Chlorine, %Calcd Found

11.59 12.23 12.86 22.86 10.00

11.42 12.05 12.85 23.10 10.36

-pKa"

2.21f0.003 3 5 2 i .01 4.43 f .01 4.83 i .01 4 . 8 5 f ,008

10.31 10.16 5 , 8 5 f .01 1 1 . 0 5 11.02 6 , 5 7 5 . 0 1 C, 61.08; H , 5.03; N, 14.50.

the establishment of a previously unavailable acidity function.

H+

Results and Discussion Comparison of the Ho and the H+ Acidity Scales.I n this work the equilibrium constants for the process of protonating positively charged species to dipositively charged ones were measured. Since an H+ function was not available, the Hoscale was used. The applicability of this was checked by plotting log (B+)/ (BH++) US. HOfor all compounds investigated. These plots are shown in Fig. 1 and 2 and demonstrate that the 5

.

i^j

F

813 -

v

0.4

-

0.2

-

Fig. 2.-Plot

-0.2

-

-0.4

-

8

7

Ho. of log ( B + ) / ( B H + 2 )us. Ho.

Analysis of the Tautomeric Equilibrium.-The results of the pKa measurements are shown in Table I. These were analyzed according to the scheme shown in Fig. 3. From the.equilibria shown there, the following equation can be derived

0 -

M

6

KT = (KJKi) I

I

2

3

1

I

4

5

Ho

Fig. 1.-Plot

of log ( B +) '( BH + 2 ) v s .

Ho.

slope of the line defined by the experimentally measured points is unity except for the last two compounds. This then shows that Ho and H+ acidity scales are identical for this system up to about HO= -7. This is not unexpected since Fuller and Schubertg have reported that H o and H+ functions are parallel in low acidity regions and Denolo has suggested that, if the charge already on the molecule is insulated from the site of protonation by several atoms, the interaction energy of the charge with the solvent will cancel in the f B / f B H + ratios. Since the Ho function used in this work was developed using substituted azobenzenes as indicators, the present series of measurements is the first known in which it has become possible to make a careful comparison of HOand E€+ scales over a wide range of acidities using structurally similar compounds. This then constitutes ( 6 ) L. A . Flexser, L P. H a m m e t t , and .4.Dingwall, J. A m . Chem. Soc., 67, 2103 (1935). (7) H . H. JaffC and R . U'. G a r d n e r , ibid.,80, 319 (1958). (8) S. 5. Yeh and H . H. Jaffe, ibid., 81, 3274 (1959). (9) M . W. Fuller a n d W. hi. Schubert, i b i d . , 86, 108 (1963). (10) N C. Deno, private communication

- 1

Since K1 is not experimentally obtainable, the approximation that K 1 = KS must be made. This approximation can be justified on the grounds that inductive effects of -N+(CH~)Z,and -N+H(CH3)2 groups be very nearly equal and since no resonance forms can be written to delocalize the positive charge, the U-values for the two groups should be the same." The equation then becomes

KT = (KJKd

- 1

and KT can be easily ~ a l c u l a t e d . ~The j tautomeric equilibrium constants are summarized in Table 11, column A. For comparison KT'Sobtained by other TABLE I1 TAUTOMERIC EQUILIBRIUM COXSTANTS IN SUBSTITUTED 4-DAB

-

4'-Substituent

Methoxy Methyl None Chloro Bromo Trifluororneth yl h'itro

A

2 4 7 5 6 16 57

-KTB

C

39 13 15 1 7 3 0 02 05 8 9

D

E

F

1 27 4 25 698 5 29 7 23 11 25 13 10

0.53 1.44 2.10 1.80 2.61 3.57 4.36

0.60 1.88 3.10 2.40 3.86 5.62 7.00

(11) N. C. Deno and W . L. Evans, J . A m . Chem. Soc., 79, 5804 (1957).

2211

SUBSTITUENT EFFECTSIN DIMETHYLAMINOAZOBENZENES

June 5 , 1964

H

H

I

I1

IV

111 Fig. 3.-The

V equilibrium scheme.

methods are given in columns B through F. Columns B and C give KT’Sobtained by Yeh and Jaffe3’ in 20% ethanol-sulfuric acid and sulfuric acid-water solvent systems, respectively. In the present work we have found that their values are only approximations, because the pKa measurements were performed on trimethylammonioazobenzene methyl sulfate. In the present work it was found that the compound, when prepared by quaternization with dimethyl sulfate, is usually contaminated with dimethylaminoazobenzene methyl sulfate. This is indicated by the deep red color of the product. Consequently pKa measurements of

(ammonium form) and 520 mp (azonium form) bands equally. The failure of his method is no doubt due to an inadequacy of this assumption. Particularly, substituents which can give rise to cross conjugation with the dimethylamino group may be expected to violate this assumption. The tautomeric equilibrium constants from spectroscopic data are probably invalid for the following reason: the spectroscopic behavior of 4-DAB and of its 4’-methoxy derivative was investigated between pKa1 and pKa,, Instead of the expected constancy of the extinction coefficient of DAB in the acidity range where the first conjugate acid is the only significant species, an “S”shaped curve was noted in the ,520 mp peak and the 320 mp peak of the conjugate acid of 4-TAB, as shown in Fig. 4. About the same behavior was exhibited by the 4’-methoxy derivative as shown in Fig. 5. From these data it is apparent that KT’Sfrom

3t

2 1

2 X Y

1.5

1

I :y I

I

I

2

1

0

3

-1

Ho. Fig. 5.-Plot of e X lo-‘ of 4’-methoxy-4-DL4Band TAB v s . Ha: -, 548 mp band of DAB; . , . . . , 354 mp band of DAB; - - - -., 354 mp band of TAB. 2

1

Fig. 4.-Plot of B X 518 m p band of DAB; . 318 mp band of TAB.

0

-1

-2

Ho. of 4-DAB and 4-TAB us. H o : -, . . . ., 318 nip band of DAB; - - - -,

Jaff6 and Yeh are only first approximations. In contrast to this, the trimethylammonioazobenzene chlorides were light yellow in color and gave perfectly consistent and reproducible pKa measurements. Column D in Table I1 gives data obtained by the spectrophotometric method of S a ~ i c k i . ~ ‘Column E gives data obtained by the spectrophotometric method of Yeh and Jaffg3’ and column F gives data obtained by the same method modified by a correction suggested by Wepster.I2 Sawicki’s method assumes that substituents affect the molar’extinction coefficients of the 320 (12) B. M. Wepster, private communication cited in ref. 33.

spectral data will be quite unreliable, since there will appear to be large changes in KT with relativelysmall changes in the acidity of the solution. Such changes are shown in Table I11 when calculations are performed a t different acidities. TABLE I11 CHANGES IN KT FROM SPECTROSCOPIC DATAWITH CHANGES IN ACIDITY Ho

Compound

+0.3 -2 $2 0

4-DAB 4-DAB 4’-Methoxy-4-DAB 4’-Methoxy-4-DAB

Method of Method of S a ~ i c k i ~Yeh ~ a n d Jaffb3j

8.9 3. i 1.1 1.6

i.3 2.0 0.038 0.43

It is quite unlikely that the tautomeric equilibrium constant changes as much as indicated by these calculations. Attempts to relate these spectral changes to

M. ISAKS AND H . H. JAFFP

2212

-08

0

-04

Fig 6 -Plot

08

04 a +and a

12

-

of log K T os c + and

u-

changes in Ho or to changes in total sulfuric acid conc e n t r a t i o n ~met ~ ~ with failure. One of the more likely explanations of this effect is the possibility that the observed spectral changes are due to protonation of the solvent shell which is solvating the azobenzene moiety. This could be analyzed as B .S

477.1% BH+,S

B'H+,S

Vol. 86

and were able to show that there is a linear relationship between increase in the extinction coefficient of the 320 mp peak and the decrease in the extinction coefficient of the 320 mp peak of the first conjugate acid of 4-DAB with increase of the acidity of the solution. This observation they ascribe to an acidity-dependent shift from ammonium to azonium form; however, these authors fail to provide any rationale for the shift. Application of the Hammett Equation.-The pKa of the 4'-substituted 4-TAB chlorides gave an almost perfect fit with u + values. The fit was obtained by means of a least squares treatment which yielded a correlation coefficient of 0.999. The quantities found by the least squares treatment have been summarized in Table IV. Yeh and Jaff6I5 observed t h a t series of disubstituted azobenzenes, in which one substituent was held constant and the other varied, gave p-values which varied linearly with the u of the constant substituent. The p of 2.79 obtained here for the trimethylammonioazobenzenes is in excellent agreement with the correlation of these authors, who also found that u + constants were necessary to obtain a good fit. This is no doubt due to contributing resonance forms such as

7 4 7.1 7.l BH+.SH+

B'H+.SH+

BH*+',SH+

where B and S are the base and the solvent, respectively. At the present moment not enough constants are known to allow analysis of the above system. However, work on this is in progress. TABLE IV LEASTSQUARES ASALYSIS OF pK,'s u CONSTASTS PK

Valuea

a-

P

r PK3

S

SP

PKO 7

3.272 0,951 ,635 ,477 -4.56

Table V. TABLE V CALCCLATED

WITH a+

VARIOUS a + and

0 -

2.790 0,999 ,018 ,015 -4.41 3.612 0.996

2.777 0.994 PKz S ,185 222 SP 147 ,135 PKQ -5.26 -5.04 P 3.526 2.711 T 0.996 0.995 184 ,212 pKa2 S ,146 129 SP PKo -5,34 -5,13 0.841 0.674 P r ,916 ,968 log K T S ,205 ,131 ,164 ,079 SP log KT' 830 793 a p is the slope, Y is the correlation coefficient, s is the standard deviation, s p is the standard deviation from t h e slope, and pKo is the calculated p K of the unsubstituted compound. P

From the diagram in Fig. 3 it can be seen that K z = K I K ~ .The substitution of Ka for K1 will then permit the calculation of K1. These values are shown in

After this work was completed, we found that Kaminsky and Bernschtein14 had also noted this effect ( 1 3 ) \V, H . Layne, H. H. JaffC, and H. Zimrner, J . A m . Chrm. SOC.,86, 1816 (1963).

pKn

O F 4'-SUBSTITUTED

4-DAB

Substituent

-pKz

Substituent

-pKa

Methoxy Methyl ;\'one Chloro

2 59 4 14 5 28 5.53

Bromo Trifluoromethyl Nitro

5.63 7 07 8 36

u--Values might be expected to apply to K z since structures such as

should contribute. When this fit was attempted, the results were disappointing since a correlation coefficient of only 0.951 was found. The other quantities can be seen in Table IV. Although no valid resonance structures can be written to invoke U + constants, with these a much better correlation was found. However, when a "mixed set" of u + and u- values was used, an equally good fit was obtained. In a mixed set of values, U - is used for mesomerically electron-withdrawing substituents and U + is used for mesomerically electron-donating ones. The correlations are again shown in more detail in Table IV. It therefore appears reasonable that contributions from resonance forms which would lead to use of u - constants to the ground ( 1 4 ) I. L. Kaminsky and I. J. Bernschtein in "Lectures on Problems in Development of Correlation Equations in Organic Chemistry," T a r t u Peoples University, T a r t u , U.S.S.R., 1962, p p , 333-341. (15) S. J. Yeh a n d H. H. JaffC, J . A m . Chem. SOC., 81, 3279 (1959).

June 5 , 1964

ENAMINES I N 1,3-DIPOLAR ADDITIONREACTIONS

state energy of the molecule is a very good possibility. The KT data indicate t h a t in the first conjugate acid the form present in major proportions is the azonium form (11). Since pKn is the pKa of the azonium form, i t could be expected t h a t pKaz would be quite cIose to pKz. This was found to be the case. The results of the least squares analysis are shown in Table IV. It should be noted that the Hammett plots of pK3 and pKn are quite good straight lines. This is in contrast to work of Zollinger3' and H e i l b r ~ n n e who r ~ ~ could obtain good fits only when points representing the more active substituents such as 4'-nitro and 4'-cyano were omitted. This is due to their basic assumption t h a t K T can be estimated by the spectroscopic method of SawickiI3' as discussed above. When the Hammett equation was applied to log KT it was found that, with u+, a correlation coefficient of 0.916, and with u+u-, one of'0.968, could be obtained. The appropriate data are shown in more detail in Table IV and a graphical representation is shown in Fig. 6. T h a t the use of u+u- constants yields the better fit can be rationalized on the basis of the resonance forms

VI

2213

and

w In structure VI substituents capable of exerting an electron-withdrawing effect by resonance would tend to make the dimethylamino group less basic, leaving the azo group effectively uncharged. This would tend to increase KT and would require u--values. Structures such as VI1 would demonstrate the effect of electrondonating groups in increasing the basicity of the azo group and leaving the dimethylamino group effectively uncharged. Such structures would lead to a fit with u+. Both structures tend to substantiate the view t h a t the tautomer protonated on the azo group should be predominant.

[ CONTRIBUTIOX FROM THE DEPARTMENT O F CHEMISTRY OF ARIZONA STATE UNIVERSITY, TEMPE, ARIZ.]

Enamines as Dipolarophiles in 1,3-Dipolar Addition Reactions' BY MORTON E. M U N KA N D YUNGK I KIM^ RECEIVED JAKUARY 13, 1964 The investigation of the reaction of phenyl azide with a series of enamines clearly demonstrates that the are the result of elecexclusive products of 1,3-dipolar addition, l-phenyl-5-amino-4,5-dihydro-l,2,3-triazoles, tronic control. The negative end of the azide dipole, i . e . , the nitrogen bearing phenyl, is directed to that carbon atom of the unsaturated linkage bearing the electron-releasing amino group. The fact t h a t conjugation with an amino group "activates" the olefinic linkage toward 1&dipolar addition supports the electrophilic nature of the reaction.

Of the varied olefinic dipolarophiles successfully employed in intermolecular 1,3-dipolar addition reactions, the predominant number involve an unsaturated linkage that is either strained or conjugated to aromatic and/or electron-withdrawing groups. 3 , 4 However, only relatively few isolated examples of the successful utilization of dipolarophiles in which the olefinic linkage is conjugated to an electron-releasing group have appeared in the 1iterature.j The present report, describing the addition of phenyl azide to a series of enamines,6 clearly demonstrates the important role that an electron-releasing substituent a t the site of unsaturation can play in determining the course of 1,3-dipolar additions. ( I ) Presented before the Division of Organic Chemistry a t the 145th National Meeting of t h e American Chemical Society, New York, N . y . ,Sept. 10, 1863 (2) Supported by a Parke, Davis and Co. Research Scholarship. (3) T h e facile intramolecular cycloaddition of nitrones t o "unactivated" olefinic linkages t o yield fused bicyclic isoxazolidines has been reported b y S . A . LeBel and J. J. Whang, J . A m . Chem S o c . , 81,6334 (1959). (4) R. Huisgen, Angew. Chem., 76, 604 (1963), provides a recent and comprehensive review of the entire field of 1,3-dipolar addition reactions. ( 5 ) (a) K. Alder and G. Stein, A n n . , 601, 1 (19331, suggest t h a t the reactions of cyclohexanone and cyclopentanone ani1 with phenyl azide are explicable in terms of a 1,3-dipolar addition to t h e tautomeric enamine forms. (b) R . Huisgen, M. Seidel. G . Wallbillich, and H. Knupfer. Tetrahedron, 17, 3 (1962), report the cycloaddition of diphenylnitrilimine t o ketene diethyl acetal (c) R. Huisgen, Angew. Chem., 7 6 , 601 (19631, reports the successful addition of 0-nitrophenyl azide t o 2.3-dihydropyran (6) Recent papers b y R. Fusco, G. Bianchetti, and D . Pocar, Gaze chim. ital , 91, 849 (1961) [Chem Abrtv , 66, 14019 (1962)], and G. Nathansohn. E . Testa, and N. Dimola. E x p e v i e n l i a , 18, 57 (1962), which appeared after t h e inception of the s t u d y described in this manuscript, report the successful condensation of aromatic azides with enamines.

The directive influence of the amino group was established on the basis of the isomeric 5-(l-piperidino)4,5-dihydr0-1,2,3-triazoles,~ IIa (70% yield) and I I b (91% yield), respectively, arising from the addition of phenyl azide to the isomeric piperidine enamines of acetophenone and phenylacetaldehyde (Ia and Ib, respectively). Thus the nitrogen atom of the azide dipole bearing phenyl is directed to that carbon of the unsaturated linkage bearing the amino group. Reaction was conveniently effected by mixing equimolar amounts of reactants a t room temperature in the absence of solvent. Triazoline structures I I a and I I b were assigned on the basis of elemental analysis and their facile conversion, in yields greater than 90%, to the known triazoles, 1,5diphenyl- 1,2,3-triazole ( IIIa)8 and 1,4-diphenyl-1,2,3triazole (IIIb),* respectively, upon treatment with refluxing 2 N methanolic potassium hydroxide. I t appears that the stabilization of the transition state of the elimination step provided by the incipient aromaticity of the 1,2,3-triazole system accounts for the rather facile departure of a poor leaving group. It is interesting to note that dilute aqueous acid promotes a similar quantitative elimination of piperidine in the case of triazoline I I a ; the isomeric triazoline I I b gives rise to more deep-seated decomposition products under these conditions (vide infra). ( 7 ) 4,5-I)ihydro-l,2,3-triazoles will hereafter be designated as "triazolines." (8) W. Kirmse and L. Horner, A n n . , 614, 1 (1958).