Rate data for the hydrolysis of 111ethy1, ethyl, n-propyl, n-butyl lnethanesulphonate have been determined over sufficient range of temperature to pcrlnit an evaluation of the corresponding enthalpy, entropy, and heat capacity terms for the activation process. Changes in these derived parameters are related to characteristic dilferences in solvation and mechanism as a consequence of changes in the struct~lre of the hydrolyzing ester.Our ltnowledge collcerning the details of hydrolysis of simple allcyl esters of strong acids in water have been extended recently by a study of isotope effects arising from changing the medium from Hz0 to D2O (1, 2, 3) and from various secondary deuterium isotope effects (4,5, 6). In principle, further information should be made available from a consideration of the changes in the derived parameters, AH*, AS*, ACT,* but the theoretical basis for the interpretation of changes in these parameters suffers from such uncertainty that to an important degree, relating changes in these paraineters with changes in structure amounts to no more than confirming changes anticipated from other evidence of mechanism. The greatest uncertainty would appear to lie in AH* and AC,,*, differences in As+ being somewhat easier to interpret. Our purpose in this paper, therefore, was to determine the rate data for hydrolysis of a series of alkyl metl~anesulphonates over sufficient range of teinperature that reliable values of the enthalpy, entl-opy, and heat capacity of activation could be determined, and to show how changes in these parameters are consistent with the solvation of sulphonates and with changes to be expected in mechanism from lengthening the carbon chain.
EXPERIMENTAI, METI-IODS A N D i\/IATERl.AL,SThe methanesulpho~lic esters used in this study were synthesized by conve~ltional methods (7,8). The physical constants are given in Table I. T h e method used in determining rates of hydrolysis, in temperature measurement and control were identical in all respects with those used in determining ltinetic data for the be~lzenesulphonates (9)
