Mechanisms & Optical Activity (Edexcel International A Level Chemistry): Revision Note
Mechanisms & Optical Activity
Optical activity can be used to suggest the mechanism of a chemical reaction
This is particularly the case for nucleophilic substitution
Nucleophilic substitution can occur via an SN1 or SN2 mechanism
SN1 mechanism
The SN1 mechanism is a two-step reaction
In the first step, the C-X bond breaks heterolytically and the halogen leaves the halogenoalkane as an X- ion
This leaves a trigonal planar, tertiary carbocation
In the second step, the planar, tertiary carbocation is attacked by the nucleophile
The nucleophile is able to attack from either side of the planar carbocation, which results in the formation of a racemic mixture
Therefore, a reaction with an SN1 mechanism will produce a racemic mixture
SN1 Optical Isomers Mechanism
SN2 mechanism
The SN2 mechanism is a one-step reaction
The nucleophile donates a pair of electrons to the δ+ carbon atom of the halogenoalkane to form a new bond
At the same time, the C-X bond is breaking and the halogen (X) takes both electrons in the bond
The halogen leaves the halogenoalkane as an X- ion
For example, the nucleophilic substitution of bromoethane by hydroxide ions to form ethanol
The SN2 mechanism of bromoethane with hydroxide causing an inversion of configuration
The bromine atom of the bromoethane molecule causes steric hindrance
This means that the hydroxide ion nucleophile can only attack from the opposite side of the C-Br bond
Attack from the same side as the bromine atom is sometimes called frontal attack
While attack from the opposite side is sometimes called backside or rear-side attack
As the C-OH bond forms, the C-Br bond breaks causing the bromine atom to leave as a bromide ion
As a result of this, the molecule has undergone an inversion of configuration
The common comparison for this is an umbrella turning inside out in the wind
Inversion of configuration - umbrella analogy
Therefore, if a reaction with an SN2 mechanism starts with an enantiopure reactant then an enantiopure products will be formed
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