Cumulative Substitution/Elimination - Online Tutor, Practice Problems & Exam Prep

The leaving group in nucleophilic substitution reactions is crucial because it must be able to stabilize the negative charge it acquires after departure. A good leaving group is typically a weak base, as weak bases are more stable with a negative charge. Common leaving groups include halides (Cl⁻, Br⁻, I⁻) and sulfonate esters (e.g., tosylate, TsO⁻). The ability of the leaving group to depart efficiently affects the reaction rate and mechanism (S_N1 or S_N2). In S_N1 reactions, the leaving group departure is the rate-determining step, while in S_N2 reactions, the leaving group leaves simultaneously as the nucleophile attacks.

Markovnikov's rule states that in the addition of HX (where X is a halogen) to an alkene, the hydrogen atom will attach to the carbon with the greater number of hydrogen atoms (the less substituted carbon), while the halogen will attach to the carbon with fewer hydrogen atoms (the more substituted carbon). This occurs because the more stable carbocation intermediate forms during the reaction. For example, in the addition of HBr to propene, the hydrogen attaches to the CH₂ group, and the bromine attaches to the CH group, resulting in 2-bromopropane as the major product.

Stereochemistry is significant in elimination reactions, particularly in E2 mechanisms, where the anti-periplanar geometry is required. This means that the hydrogen atom being removed and the leaving group must be on opposite sides of the molecule. This arrangement allows for the proper orbital alignment necessary for the reaction to proceed. In cyclic systems, this requirement can lead to specific stereoisomers as products. For example, in the elimination of HBr from 2-bromobutane, the anti-periplanar requirement can lead to the formation of trans-2-butene as the major product.

A flow chart helps determine the mechanism of a reaction by guiding you through a series of questions based on the reactants and conditions. Typically, you start by identifying the type of substrate (primary, secondary, tertiary) and the nature of the nucleophile or base (strong/weak, bulky/non-bulky). The flow chart will then direct you to consider factors such as the solvent (protic or aprotic) and temperature. By following these steps, you can narrow down whether the reaction proceeds via S_N1, S_N2, E1, or E2 mechanisms. For example, a tertiary substrate with a strong base in a protic solvent likely undergoes an E2 elimination.

The key differences between S_N1 and S_N2 mechanisms lie in their kinetics, stereochemistry, and conditions. S_N1 reactions are unimolecular and involve a two-step process: formation of a carbocation intermediate followed by nucleophilic attack. They exhibit first-order kinetics and often lead to racemization due to the planar nature of the carbocation. S_N2 reactions are bimolecular and occur in a single step where the nucleophile attacks the substrate simultaneously as the leaving group departs. They exhibit second-order kinetics and result in inversion of configuration at the carbon center. S_N1 is favored by tertiary substrates and polar protic solvents, while S_N2 is favored by primary substrates and polar aprotic solvents.