The Rate and Mechanism of Hydrolysis of Benzhydryl Chloride in

BY WILLIAM TAYLOR. Three current mechanisms which have been adopted to interpret the first-order reaction be- tween an alkyl halide and a relatively h...
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WIIATAM TAYLOR (CONTRIBUTION PROM THE: CHEMISTRY

Vol. 60

DEPARTMENT OF THEPOLYTECHNIC]

The Rate and Mechanism of Hydrolysis of Benzhydryl Chloride in Acetone BY WILLIAMTAYLOR

Three current mechanisms which have been adopted to interpret the first-order reaction between an alkyl halide and a relatively high concentration of water, alcohol, or acetic acid are those of (a) Hughes and Ingold' who assume partially for secondary and completely for tertiary, a slow uniwolecular ionization of the halide as the rate-determining stage followed by a rapid reaction of the organic cation with a solvent molecule; (b) Taylor,2 and Olson and Halford,g who assume ior alkyl halides generally a one-stage bimolecular reaction involving the simultaneous addition and dissociation of the reactants, according to the ideas of London,4 P ~ l a n y i ,and ~ Olson,fi and Cc) Hammett,7 who assumes a poiymoEecdar reaction, which depends essentially upon the affinity of alcohol or water molecules for halide ion, reaction taking place within something of the nature of a solvation complex. Taylor2' showed that the reaction of r-butyl bromide with water of low concentrations in acetone a t 50' was kinetically of the second order and that therefore the mechanism of hydrolysis could not be unimolecular but is presumably bimolecular. Olson and Halford,2 a t about the same time, showed that the hydrolysis and alcoholysis of t-butyl chloride in aqueous methanol are both second-order reactions, if the fugacities of the reactants (as measured by their vapor pressures) and not their concentrations are employed in calculating the rate constants. These results appear to remove the possibility of mechanism (a). There remain (bj and (c). Mechanism ( c ) was based partially on Hammett and co-workers7finding that a t 25" when benzhydry1 chloride (or a-phenylethyl chloride) and small concentrations of water (or of ethyl alcohol) are both dissolved in acetone, the rate of reaction is very low, whereas a t the same temper(1) Gleave, Hughes and Ingold, J Chem Soc 236 (1'3'351 (2) Taylor, rbrd , (a) 344, (b) 992, (c) 1853, (d) 1962 (193i) (3) Olson and Halford. Trrrs JOUR\AI., 69, 2644 (1'137) 14) London, 2 Elekfrorhcm , 35, 652 (1929) ( 3 ) Meet and Polanyr, Z p h y s ~ k Chem , B19, 164 (19.12) Reigmdtin, Polanyi and Szabo, tbid , B20, 161 ( I 933) < R ) Olson, J . Chem F h > r 1 418 f I 9 3 o ) , Olwn and l'oge I HI^ J I I U K N A L , 56, 11590(1934) ) ;1 bteigman arid Hammctt z h ~ i l 59, , 153h (1937) Fannarci and Ilammett i h a i 6 9 , 2 i 1 0 I '

ature in dry or wet ethyl alcoholic solution the rate of reaction is high. The purpose of the present investigation was to find whether or not this state of affairs obtains with benzhydryl chloride a t 50'. In brief i t does not, since there is a measurable rate of hydrolysis of benzhydryl chloride in acetone containing 1, 2, 5 or 10 g. of water per 100 cc. of solution a t this temperature. (These solutions are referred to as containing 1, 2%, etc., of water.) Thus, to this extent, the basis of the polymolecular mechanism (c) is weakened. Positive evidence in support of mechanism (b) was sought along the lines of the previous work with t-butyl bromide.2c Since, when either 2 or 10% aqueous acetone was used, no s-tetraphenyldimethyl ether could be detected in the reaction products (compare Ward8) but only benzhydrol, the sole reaction between benzhydryl chloride and water which occurs under these conditions can be represented ki

PhACHCl

+ HzO 2PhzCHOH 4-HC1 kl

and is reversible. Figure 1 shows the dependence of the rate of hydrolysis upon the concentration of water even at the lowest water concentrations. However, as with the hydrolysis of t-butyl bromide in acetone, a slow reaction persisted beyond the equilibrium position due again presumably to the formation of mesityl oxide and other acetone condensation products in the presence of hydrogen chloride. This caused the elimination of water and hence the continued hydrolysis of benzhydryl chloride. The slow increase in acidity thus produced was approximately directly proportional to time for a considerable time interval and thus the equilibrium position for any one system was determined by extrapolatioii of the straight-line portion of the curve back to the .r-axis. From the equilibrium constants I< = k , / k 2 the equilibrium positions ( n ) were calculated,2c n being the equilibrium value of s. As in the case of t-butyl bromide there is close agreement between the calculated values of ?t and those obscrved for the forward reactioii (Table T ) ( 8 ) h a d , J C h r m hoc 2285 (1927).

Sept., 1938

2095

HYDROLYSIS OF BENZHYDRYL CHLORIDE IN ACETONE

TABLE I Showing the practical identity of observed and c ~ c U lated values of TZ, the equilibrium position, it being assumed that both reactions are kinetically of the same order. 2nd order 2nd order [HzO] [PhaCHCI] ki ka K 0.0974 0.00230 0.658 0.00350 ,1052 ,00415 .556 ,00746 2.7778 .lo64 .0171 .127 ,134 5.5556 .1170 .Of336 .0186 3.42

0.5556 1.1111

n, obsd. n,calcd. 0.0125 0.0127 .0270 .0255 .OS42 .OS60 .1140 .1157

The catalytic effect of water on the hydrolysis reaction, as shown by the increase in the values of the second-order coefficient k1 with a rise in the water concentration, is ascribedg to the dissociating effect of water on itself in acetone solution i. e. HzO

(HzO),

1 'nHzO COMez

the associated form being assumed to be relatively unreactive, compared with the simple form, toward the alkyl halide. Constant values of kl,therefore, could not be expected since these were calculated using ordinary water concentrations, owing to lack of information regarding the active mass of the

The value of k1 employed - - in the calculation of the equilibrium constant K = kl/k2, where k2 is the second-order rate constant for the reverse reaction, was that extrapolated a t t = 0 from the plot of kl against t. Typical data for the forward reaction in 1 and 5% aqueous acetone are given in Table 11. TABLE I1 IN TYPICAL KINETICDATAOF THE FORWARDREACTION ACETONEAT 50 1% 5% b = 0.0974

a = 0.5556 1

X

ki

22.4 .0.0030 0.00251 70.5 .0072 .00197 100 .0095 .00187 146 .0118 .00161 237 .0170 ,00148 334 .O2l0 .00133 ,0228 ,00102 450 671 ,0250 .ooo82

837 1006

,0266

.0%80

, ,

..

a

= t

2.7778 X

b = 0.1064

ki

1.65 0.0080 0.0170 3.0 ,0140 .0169 5.35 ,0224 ,0159 8.43 ,0320 .0154 11.53 ,0420 .OM8 23.5 ,0660 ,0150 29.5 ,0740 ,0147 48 ,0830 .. 218 ,0842 ..

simple form. 0.10 From the evidence presented, 2 then, the view is taken that the $o.08 hydrolysis of benzhydryl chloride in acetone is a second-order reac- 4 tion and that the mechanism is bix molecular. Experimental 0.04

ao.O6

2 Y

Materials.--"AnalaR" acetone, refluxed for ten hours over potassium 0.02 permanganate and calcium oxide, Benzhydryl 0.00 boiled at 56-56.5'. chloride, prepared by the method 0 100 200 300 400 Time, hours. of Farinacci and Hammett, had b. 190-1910 (47 mm.) (Calcd. : Fig. 1.-Effect of water on the rate of hydrolysis of benzhydryl chloride in acetone. Water "Percentages": 9, 1; 8, 2; 0 , 5 ; 0,10. C1, 17.53. Found: C1, 17.54). The determination of the second-order rate Benzhydrol (commercial) recrystallized from alcocoefficients of the reverse reaction in acetone, hol melted a t 68". Rate Measurements.-These were made a t 50". containing initially the same concentrations of The procedure was identical with that used for water as for the forward reaction, was complit-butyl bromide.2c As with this compound a dark cated by the rapid removal of hydrogen chloride color developed in the reaction liquids of lower by the acetone. These constants were therefore water concentrations. The values of k for the for- calculated from the equation ward reaction were calculated for an irreversible [HCI removed by PhzCHOH]/t = k2[PhzCHOH][HCl] second-order reaction from k~ = [2.303/t(a - b ) ] t being the time in hours, and all concentrations loglo b(a - x)/a(b - x), t being the time in hours, being in g. moles/liter, the two latter being mean and a and b the concentrations (in g. moles/liter) concentrations for any one time interval. The of water and benzhydryl chloride, respectively. amount of water formed by the condensation of acetone under the influence of hydrogen chloride ( 8 ) Taylor, J , Chrm, Sac., 840 (1938).

'

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WILLIAMTAYLOR

was so great as not only greatly to retard the formation of benzhydryl chloride in all except the initial stages, but ultimately even to cause the slow hydrolysis of that already formed, as shown by the rapid decrease in acidity giving place to a slow increase and this in spite of the continuous and simultaneous removal of hydrogen chloride by the acetone. Hence the equilibrium positions could not be observed tor this reverse reaction. Typical data for the reverse reaction in 1 and 5% aqueous acetone are shown in 'Table 111. TABLE I11 TYPICAL KINETICDATAOF THE REVERSE REACTION IN ACETONE AT 50 In column C is shown the rate of removal of hydrogen chloride by 1 and 5% aqueous acetone containing no benzhydrol. O

WCll

c

[HCl]

HCI removed

[by PhXHOH]

kz

1%

(Ph2CHOIII = 0.0929, [HCl] = 0.1090, [HzO] = 0.5556 0 . oooc 0 0.1090 C).1090 .0010 0.11 .OS60 .0870 .0034 0.685 0.65 ,0816 ,0850 0840 ,0124 601 2.8 ,0716 .Ol53 ,648 3.38 .0682 . 0835 .OS30 .0170 ,697 3.8 .0660 19.5 .05lO 0780 ,0270 .. 68.5 0354 0635 ,0281 125 ,0340 . 0550 ,0210 .. 332 ,0374 ..

1701. GO

Benzhydryl chloride (2.2 g.) in aqueous acetone (100 cc.) was kept a t 50' for two hundred and forty and twenty-four hours, respectively; excess anhydrous sodium carbonate was added to remove water and acid. After filtering, and distilling the acetone, approximately 3 cc. of brown oil containing some crystalline solid was obtained; (1) the product had a faint odor of mesityl oxide but no 2,4-dinitrophenylhydrazone could be obtained from i t ; ( 2 ) that from 2% aqueous acetone contained considerable unchanged benzhydryl chloride (Found: C1, 5.6) whereas that from 10% aqueous acetone contained negligible chlorine; ( 3 ) to 2 cc. of the product in each case was added ethyl alcohol (2 cc.) but there was no solid residue and hence no s-tetraphenyldimethyl ether had been formed.8 Addition of water to the alcoholic solution gave benzhydrol only (m. p. and mixed m. p. with authentic specimen).

Summary

The hydrolysis of benzhydryl chloride and the action of hydrogen chloride on benzhydrol have been studied kinetically in acetone containing low concentrations of water. The hydrolysis reaction, under these conditions, yields benzhydrol and hydrogen chloride as the only reaction prod5% ucts. Assuming that both are second-order [PhzCHOH] 0.0929, [HCI] = 0.1160, [HsO]= 2.7778 reactions, there is close agreement between the 0.1160 0.0000 0 0.1160 calculated equilibrium positions and those ob.0020 0.140 .1106 .1125 1.43 .0180 .114 served for the hydrolysis reaction, with different .0940 .1120 18.3 initial concentrations of water. This agreement .0180 .. .0920 .1100 67 163 ,0930 . loso .0150 indicates that the assumption is correct; and 33 1 .0936 .. thus for both reactions a bimolecular mechanism is presumed. Examination of Reaction Products.-These were examined in 2 and 10% aqueous acetone. LONDON,ENGLAND RECEIVED MAY25, 1938 I

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