Elimination Reactions in Cyclic Systems. V. General Base Catalysis of

Eliminations in the Cyclohexane and Cyclopentane Series. BY JOSEPH WEINSTOCK, R. G. PEARSON. AND F. G. BORDWELL. RECEIVED. NOVEMBER...
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July 20, 1936

BASECATALYSIS OF cis [CONTRIBUTION FROM THE CHEMICAL

AND

trans ELIMINATION

347.7

LABORATORY O F NORTHWESTERN UNIVERSITY]

Elimination Reactions in Cyclic Systems. V. General Base Catalysis of cis and trans Eliminations in the Cyclohexane and Cyclopentane Series BY JOSEPH WEINSTOCK, R. G. PEARSON AND F. G. BORDWELL RECEIVED NOVEMBER 3, 1955 Both the cis and trans eliminations from 2-p-tolylsulfonylcyclohexyl and 2-p-tolylsulfonylcyclopentyl p-toluenesulfonates have been shown to be subject to general base catalysis. This demonstrates the absence of a stable carbanion intermediate in any of these reactions. Eliminations with triethylamine are all slower than those with the weaker base trimethylamine indicating the operation of a steric effect in these reactions. The smaller ratio of rates, k o r / k M e 3 N and k E t r N / k l e l N , for cis eliminations than for trans eliminations establishes the importance of steric and electrostatic repulsions in favoring trans over cis eliminations in these systems. The fact that cis and trans eliminations in the cyclopentane series with trimethylamine proceed at comparable rates, indicates that the ability t o undergo trans elimination via a planar four-centered transition state is not a factor of primary importance in influencing the rates of these reactions.

At least three factors have been mentioned to since the H-0 and H-N bonds are relatively explain the more rapid E2 elimination of trans acidic. This mechanistic path has been established than cis groupings in cyclohexane derivatives. for the reverse aldol reaction of diacetone alcohol.* These are (1) trans eliminations are concerted CH3 CH3 whereas cis eliminations proceed by an energetically I unfavorable two-stage mechanism involving a -0-C-CH2COCHa + O=A THaCOCHa carbanion intermediate,2 (2) steric and electrostatic I I repulsions between the base and the reacting moleCHa CHI cule are less for trans than for cis elimination^,^ and (3) planar four-centered transition states with It seems certain that the ElcB reaction course a trans arrangement of the groups to be eliminated will be observed in H-C-C-Y systems when H-C are energetically f a v ~ r e d . ~ is made sufficiently weak and C-Y is sufficiently Cristol originally suggested the carbanion inter- strong. mediate mechanism (labeled ElcB by Ingold) to I n the previous paper in this seriesgi t was shown account for the relative slowness of cis elimination that trans eliminations from cis-2-(p-tolylsulfonyl)of hydrogen chloride from the p-isomer of benzene cyclohexyl and cyclopentyl p-toluenesulfonates (I1 hexachloride.2 Cristol and Fix5 investigated the and IV, respectively) were favored over cis eliminapossibility of deuterium exchange during this reac- tions from the corresponding trans isomers (I and tion. They interpreted the very small amount of 111) by factors of 435 and 20. Since the H-C deuterium exchange observed as supporting a bond in these compounds has been rendered acidic carbanion mechanism, but Hughes, Ingold and by the presence of an a-sulfonyl group the likeliPasternak6 have interpreted the same results as hood of the formation of a carbanion intermediate evidence for the absence of a carbanion inter- appeared to be greater than in the benzene hexamediate. chloride case.2,5-6A test for the presence of a Although no clear-cut example of the operation stable carbanion intermediate was therefore made of the ElcB mechanism in eliminations from a using a kinetic approach.1° saturated system to form a carbon to carbon double In base-catalyzed elimination reactions of the bond appears to have been reported a t this writing, ElcB type there is good reason to believe that a reaction course of this type will be followed in a system, I I ki I I J_ B :H + -C-C-Y (fast) H-C-C-Y, where H-C is sufficiently acidic. B : + H-C-C-Y I 1 kz I I This mechanism is apparently operative in the base-initiated elimination of hydrogen chloride from ClCH=CClZ, since extensive deuterium exchange has been observed under conditions milder than those used to promote eliminations.7 I n elimination reactions from systems such as H-0-C-Y and H-N-C-Y the reaction course the reaction will involve an initial ionization of the must be frequently that of a two-stage elimination, substrate which comes to equilibrium, followed by a rate-controlling reaction of the resulting anion, (1) This investigation was supported by the Officeof Naval Research The rate will be a function of the concentration of under Contract No. N7 onr-45007. The results were reported in a

+

+

preliminary fashion in THISJOURNAL, 76, 4748 (1954). (2) (a) S.J. Cristol, THISJOURNAL, 69,338 (1947): (b) S. J. Cristol, N . L. Hause and J. S. Meek, i b i d . , 73, 674 (1951); (c) S. J. Cristol and W. P. Norris, i b i d . , 76, 3005 (1954). (3) W. Huckel, W. Tappe and G.Legutke, A n n . , 643, 191 (1940). ( 4 ) D.H . R. Barton and E. Miller, THISJOURNAL, 72, 1066 (1950). (5) S. J . Cristol and D. D. Fix, i b i d . . 76, 2647 (1963). (6) E. D.Hughes. C . K . Ingold and R . Pasternak, J. Chem. Sac., 3832 (1953). (7) L. C. Leitch and H. J. Berstein. Can. J. Rcsrursh, 28B, 35 1950); S. I. Miller and R. M. Noyes, Jr., THISJOURNAL, 74, 636 1952).

I 1

the anion, -C-C-Y, and the anion concentration

I I

will be in turn a function of the ratio of the concentration of the base, B, and its conjugate acid, ( 8 ) I,. F. Hammett, “Physical Organic Chemistry,” McGrnw-Hill Book Co., Inc.. New York, N. Y . , 1940,p. 344. (9) J. Weinstock, R . G.Pearson and F . G. Bordwell, THISJOURNAL, 7 8 , 3468 (1956). (10) A. A. Frost and R . G. Pearson, “Kinetics and Mechanism,” John Wiley and Sons, Inc., New York, N . Y.. 1953, pp. 207-208.

3474

J. WEINSTOCK, R. G. PEARSON AND F. G. BORDWELL

B : H + . Since in aqueous solution this ratio depends on the hydroxide ion concentration B:

+ HOH Jr B : H + + OH-

such reactions appear to be catalyzed only by hydroxide ions (specific hydroxide ion catalysis). On the other hand, if the reaction proceeds by way of a concerted path, or a rate-controlling ionization followed by a rapid reaction of the anion, the reaction rate will be the sum of the reactions of all bases present (general base catalysis). From a mechanistic standpoint general base catalysis means that removal of a proton is involved in the rate controlling step. In order to determine whether the cis and trans eliminations of I-IV previously describedg were subject to specific hydroxide or general base catalysis, the rates were studied with trimethylamine and triethylamine in the presence of varying concentrations of the corresponding salt. Results The rates of reaction of I, 11, 111, IV and V9 with the amines were measured conductometrically in 50% aqueous dioxane solutions buffered by the presence of some of the amine salt. The base was used in large excess so that pseudo first-order kinetics were observed. The rates were obtained by plotting log R / ( R - R,) against time," and multiplying the slope by 2.303. The second-order rate constants (kl) were obtained by plotting the observed first-order rate constants, obtained from a t least three different dilutions of the buffer stock solution, against amine Concentration. According to the equation kobed =

kl(amine)

+ k2(OH-)

the slope of such a plot is equal to the secondorder rate constant. The data used to obtain a typical first-order rate constant are given in Table I for the reaction between trimethylamine and IV. RATEOF Time (sec.)

THE

TABLE I REACTION OF TRIMETHYLAMIXE~ WITH IV 50y0 AQUEOUS DIOXANEAT 25"

Resistance (ohms)

log

Time

Resistance

IN

log

(R/R - R) (sec.) (ohms) (R/R- R ) 31 1730 0.7612 300 1540 1.1461 50 1710 ,7853 350 1520 1.2279 75 1690 ,8159 400 1510 1.2758 100 1660 ,8579 450 1495 1.3617 126 1645 ,8837 500 1490 1.3950 600 1475 1.5159 150 1620 ,9309 200 1590 ,9969 3500* 1430 250 1560 1.0792 Trimethylamine concentration equals 0.1914 M . Infinity reading. R a t e constant, k,, is 3.20 X sec.-l.

Vol. '78

set.-'. The variation is well within the experimental error. Discussion The fact that observed rates increased in every instance with an increased concentration of amine, even though the concentration of hydroxide ion (or the ratio of concentrations [B:]/[B:H]) remained constant, shows that these reactions are general base catalyzed. This was further tested for I, where the slower rate caused a greater error in determining the rate constant,12 by runs in which the amine concentration was kept constant and the amine salt concentration was varied. The relative constancy of the observed rates under these conditions is brought out in Table 111. TABLE I11 RATESOBSERVED FOR THE REACTION OF I WITH PIPERIDISE IN THE PRESENCE OF VARIEDAMOUNTS OF BH + Piperidine hydrochloride concn. (moles/l.)a

koh?d.

x

lo5

0.020 6.38 ,015 6.57 ,010 6.55 ,005 6.37 a I n every run the concentration of free piperidine used was 0.1200 M .

These results show that no stable carbanion intermediate is formed in any of these elimination reactions. Since the sulfonyl group stabilizes a carbanion alpha to it, i t seems extremely unlikely that a stable carbanion is present in systems where such a stabilizing influence is smaller or altogether absent.13 On this basis, in our opinion, the cis eliminations we have called attention to14 and that of the @-isomerof benzene hexachloride are best classified as E2 reactions rather than ElcB reactions. I t must be borne in mind, however, that the distinction between an ElcB mechanism and an E2 mechanism vanishes as the life-time of the carbanion intermediate becomes infinitely small. Thus experimentally all one can demonstrate is an upper limit to the life-time of the carbanion. In the reactions reported here a crude estimate of the life-time can be made in the following way. The acid ionization constant of dimethyl sulfone in water has been estimated'j to be Since the rate of deuterium exchange of dimethyl sulfone is only slightly less than the rate of cis elimination from compound I when hydroxide ion is the base,16

( 1 2 ) I n unpublished work (with T. A . Sullivan) examples of c i s eliminations of analogs of I have also been shown t o undergo general base catalysis. (13) C . K. Ingold, "Structure and Mechanism of Organic Chemistry," Cornell University Press, Ithaca, N. Y . , 1953, p. 4 2 3 , has The above method of obtaining the rate con- predicted t h a t when t h e hydrogen atom eliminated is t h e ionizing stants assumes a negligible salt effect. This was hydrogen of a pseudo-acid, t h e compollnd would undergo unimolecular conjugations f r o m its conjugate anion, t h a t is, by a n ElcB mechanism. tested by determining the rate of elimination of This is not what we have found when the pseudo-acid is a sulfone. b u t with and without added lithium nitrate with a con- may hold for stronger pseudo-acids such a s ketones, nitroalkanes stant amount of trimethylamine buffer. The and is highly probable in compounds where t h e hydrogen beinR elimsalt concentrations and second-order rate con- inated is activated by two such functional groups. (1.4) See the earlier papers in this series for several flirther examples stants were: 0.05 salt, = 1.31 lo-* 1. mole-' set.-'; 0.10 ili salt, = 1.25 X n ~ o l e - ~ ( 1 9( l5,3j )). K . G . I'earson and K . I,. Dillon, T i t i s J O U K X A L , 71, 2439 salt, = 1.28 lo-* mole-l sec.-l; 0.15 (16) K F. Bonhoeffer and J , Hochberg, 2 . f i k y s i k . Ckem.. Al84,419 (1939). (11) Reference 10, p. 35. Q

I11

total

N

N

k

k k

X

X

1. 1.

3475

BASECATALYSIS OF cis AND trans ELIMINATION

July 20, 1956

TABLE I1 RATESO F AMINE REACTIONS WITH Amine

Compound

I

I-v

IN

50% AQUEOUS DIOXANEAT 25'

Initial amine concn.

9 . 5 8 X 10-6 1 . 9 5 x 10-5 2 . 7 8 X 10-6

EtzN

0.0628 .1255 .1883

1.179 X 1.396 X 2.195 X

Piperidine

0.05894 .1180 ,1768

3.895 X 6 . 5 5 X 10-6 9 . 9 5 x 10-5

Me3N

0.06522 .1304 ,1957

2.57 4.53 6.16

doTs SOeCd,

trans-isomer

(equatorial form)

I1

kabsd. (sec.-I)

0.0846 ,169 ,254

Me3N

OTS

1.13 x 10-4

8.0 X

x x x

0.06277 ,1255 .1883

3.96 4.76 5.15

x x x

10-4 10-4 10-4

IIr

Me3N

0.06404 ,1281 .1921

8.42 16.25 25.3

x x x

10-4 10-4 10-4

Et3N

0.06273 ,09394 ,1255 ,1566 ,1882

8.80 x 12.60 X 14 33 X 17.60 X 21.62 x

10-5 10-6 10-5 10-6

x x x

10-3 10-3 10-3

\

H

\

IV

S02CrH7

Me3N

0.0638 ,0957 ,1276

1.21 1.79 2.30

x

10-4

2.87

x

10-3

9.3

x

10-4

10-4 10-4

Et3N

/

5.10 10-4

cis-isomer

\joTs

kl (1. mole-' see.-')

1.30 X lo-*

10.1

x

10-4

1.56 X ,1914 0.06273 ,1255 1882

V

0.0512 .0640 .0768 ,0896

x 8.65 x 9.78 x 1.22 x

10-3 10-3 10-3 10-2

Et3N

0.06273 ,08155 .lo04

4.86 5.82 6.93

x x x

10-3 10-3 10-3

NHs

0.0604 ,1208 .1812

7.04 1.11 1.55

x x x

10-4 10-3 10-3

I

CHz-C-H II

6.77

Me3N

OTs

H--C\-S02C7H7

3.20 X 19-3 8 . 7 7 x 10-4 13.07 X 10-4 17.20 X 10-4

H

the same ionization constant may be assumed for I. Considering trimethylamine as the base, the condi-

6.56

x

10-3

1 . 3 2 X lo-'

5.93

x

10-2

7.10

x

10-3

We may set kl/kz equal to K,K$K, which is the equilibrium constant for the first step in a twoki stage ElcB reaction. The equilibrium constant B : + HA _r B : H + + A would be of the order (10-23)(10-4)/10-14 or kz in water solution, and in 50% aqueous dik3 oxane a reaction producing two univalent ions A - --+ products from neutral molecules would be less favored by tion for general base catalysis is that k~(BH+)