In this study, the researcher compared S N 2 and E2
reaction rates for four substrates. Three of the substrates had a second halogen on the b
position in the molecule. This work also compared the behavior of two nucleophiles:
dianion I and II. You should read the abstract and look at Scheme 1 (p. 3082) and Table 4
(p. 3086).

Abstract: The gas-phase reactions of benzoate and phenolate containing dianions with a series of ‚-substituted
alkyl bromides (X-CH2CH2Br, X ) H, F, Cl, Br) have been studied in a quadrupole ion trap mass spectrometer.
Branching ratios between SN 2 and E2 products were measured and rate constants were determined. The
‚-halogens increase both the S N 2 and E2 rates, but the effect is greater for the latter process and therefore
these substituents lead to an increase in the amount of elimination. The kinetic data for the SN 2 reactions can
be analyzed via a two-parameter, linear free-energy relationship and the results indicate that field-effects (i.e.,
electron-withdrawing groups) strongly favor the reaction (FF ) 1.83). In contrast, analysis of the available
condensed phase data for these substrates indicates that halogens strongly retard the reaction (FF ) -2.04).
The dramatic reversal in substituent effects can be explained by a simple electrostatic model which suggests
that solvation causes the system to shift to a more highly ionized SN2 transition state.

1a) Draw the structure of all the alkyl halides and nucleophiles/bases used in the above
published study. 

1b.) Draw the substitution reactions carried out between nucleophile I and each of the first
three substrates in Table 4 of this article. Draw the substitution reaction of nucleophile II
with the first substrate in the table. Give the product for all the above reactions. 

Transcribed Image Text:

Table 4. Relative Rates for the SN2 and E2 Reactions of Dianions with Alkyl Bromides I CH3CH₂Br FCH₂CH₂Br E2 SN2 1.7 9.3 0.0 0.0 3.5 17.1 0.4 SN2 1.0 5.7 CICH₂CH₂Br 13.7 BrCH₂CH₂Br 35.8 EtCH₂CH₂Br 2.8 "The yield was too low for accurate partial rate measurements. II a a E2 0.1 4.7 530 780

Transcribed Image Text:

Scheme 1 c=c-O-co₂" + CH₂CH₂Br SN2 =c-Q-caCH,CH, (3) + Br ⒸC=CO-CO₂H + CH₂=CH₂ + Br (4) reactions of two dianion nucleophiles with a series of simple halides and representative reactions are outlined in Scheme 1. It can be seen that by starting with a doubly charged nucleophile, each pathway leads to two ionic products. The alkylated (SN2) and protonated (E2) nucleophiles still retain charges and therefore can be used to identify the reaction mechanism (eqs 3 and 4). A key assumption of the method is that the second charge does not radically distort the reactivity of the nucleophilic center so that the dianion can provide a good model for the properties of a singly charged nucleophile. The potential problem with a dianion is that it contains a significant amount of internal electrostatic repulsion that will be released in the course of a reaction with an alkyl halide as the charged species separate. This issue has been explored by computational methods, and for dianions with fairly large initial charge separations (~15 Å or more), the second charge has only a modest effect on the potential energy surface of a nucleophilic reaction such as an SN2 substitution.22 The effect of the second charge is limited because in reaching the transition state of an SN2 reaction, there is a relatively small increase in the charge separation so only a small amount of the internal electrostatic repulsion is released. The majority of the internal electrostatic repulsion is released after the transition state and has no effect on the kinetics or product distribution of the reaction. As a result, dianion nucleophiles can provide realistic models of singly charged analogues in these reactions.23 In a previous communication, we demonstrated the utility of the method and applied it to a series of alkyl bromides with varying substitution patterns at the a-carbon (i.e., 1°, 2°, and 3º). Here, we describe an investigation of the effect of placing electron-withdrawing groups at the ß-carbon of the substrate. Specifically, the reactions of dianions I and II with a series of O-co₂ 2-haloethyl bromides (fluoro, chloro, and bromo) have been examined. Both of these dianions were used in our previous study and the diphenylacetylene framework provides a reason- able charge separation (~14 Å) that limits the effects of internal electrostatic repulsion. It is well-known that electron-withdraw- ing groups at the B-carbon should enhance E2 rates because they stabilize the incipient negative charge that develops on the ß-carbon in the E2 transition state.2.24 Much of the previous condensed phase work has focused on systems with either a substituted aryl group or a powerful electron-withdrawing group such as nitro or cyano at the ß-carbon.25-29 Less has been reported on the effects of simple electron-withdrawing groups such as halogens. In a very early study, Olivier and Weber showed that 1,2-dibromoethane was over 100 times more reactive than 1,1-dibromoethane under elimination conditions.30 Goering and Espy³1 also found that halogens and other groups Energy Rectants Reactant Complex Transition State (8) Products (5) v Product Complex Reaction Coordinate Figure 1. Double-well potential for gas-phase ion-molecule reac- tions: (a) positive activation energy (solid line) and (b) negative activation energy (dashed line). at the B-carbon increase the E2 rate. In contrast, Okamoto and co-workers³2 found that alkoxy and chloro substituents at the ß-carbon caused a reduction in E2 rates in aqueous solution. They rationalized this result as a steric effect. As for SN2 reactions, there is evidence from condensed phase studies that electron-withdrawing groups at the ß-carbon (including halo- gens) lead to rate reductions. 32-35 In the present study, we test the validity of the generalization that electron-withdrawing groups at the ß-carbon increase E2 rates and decrease SN2 rates by determining the SN2 and E2 rate constants of the reactions of the 2-haloethyl bromides with I and II. In addition, we evaluate the relative abilities of the various halogens to stabilize/ destabilize the transition states. To support the experimental work, ab initio calculations have been completed. Given the size of the dianions, it is impractical to pursue calculations on the actual experimental systems. Instead, we have used two types of model systems. The reaction of acetate with the 2-haloethyl bromides provides a reasonable model of the reactions of the benzoate dianion, I. The other model system uses methoxide as the nucleophile. Of course, methoxide does not provide a realistic model of the phenolate nucleophile, II, because it is a much stronger gas-phase base, but it does offer insight into the effects of base strength and charge localization on the competition between SN2 and E2 reactions in the B-substituted systems. The SN2 and E2 reactions involve a single barrier and lead to a double-well potential energy surface originally proposed by Brauman (Figure 1). For each reaction, we have computationally characterized four stationary points on the surface: the reactants, the reactant ion- dipole complex, the transition state, and the products. On this type of gas-phase potential energy surface, the activation energy is defined as the energy difference between the transition state and the separated reactants. As a result, positive (Figure la) and negative (Figure 1b) activation energies are possible. Experimental Section Mass Spectrometry. All experiments were completed in a modified Finnigan LCQ quadrupole ion trap mass spectrometer equipped with (25) Bunnett, J. F.; Sridharan, S.; Cavin, W. P. J. Org. Chem. 1979, 44, 1463. (26) Crosby, J.; Stirling, C. J. M. J. Am. Chem. Soc. 1968, 90, 6869. (27) Gandler, J. R.; Yokoyama, T. J. Am. Chem. Soc. 1984, 106, 130. (28) Marshall, D. R.; Thomas, P. J.; Stirling, C. J. M. J. Chem. Soc., Perkin Trans. 2 1977, 1914. (29) Saunders: W. H., Jr. Acc. Chem. Res. 1976, 9, 19. (30) Olivier, S. C. J.; Weber, A. P. Recl. Trav. Chim. 1934, 53, 1087. (31) Goering, H. L.; Espy, H. H. J. Am. Chem. Soc. 1956, 78, 1454. (32) Okamoto, K.; Kita, T.; Araki, K.; Shingu, H. Bull. Chem. Soc. Jpn. 1967, 40, 1913.