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SN2 reaction
The bimolecular nucleophilic substitution (SN2) is a type of reaction mechanism that is common in organic chemistry. In the SN2 reaction, a strong nucleophile forms a new bond to an sp3-hybridised carbon atom via a backside attack, all while the leaving group detaches from the reaction center in a concerted (i.e. simultaneous) fashion.
The name SN2 refers to the Hughes-Ingold symbol of the mechanism: "SN" indicates that the reaction is a nucleophilic substitution, and "2" that it proceeds via a bimolecular mechanism, which means both the reacting species are involved in the rate-determining step. What distinguishes SN2 from the other major type of nucleophilic substitution, the SN1 reaction, is that the displacement of the leaving group, which is the rate-determining step, is separate from the nucleophilic attack in SN1.
The SN2 reaction can be considered as an organic-chemistry analogue of the associative substitution from the field of inorganic chemistry.
The reaction most often occurs at an aliphatic sp3 carbon center with an electronegative, stable leaving group attached to it, which is frequently a halogen (often denoted X). The formation of the C–Nu bond, due to attack by the nucleophile (denoted Nu), occurs together with the breakage of the C–X bond. The reaction occurs through a transition state in which the reaction center is pentacoordinate and approximately sp2-hybridised.
The SN2 reaction can be viewed as a HOMO–LUMO interaction between the nucleophile and substrate. The reaction occurs only when the occupied lone pair orbital of the nucleophile donates electrons to the unfilled σ* antibonding orbital between the central carbon and the leaving group. Throughout the course of the reaction, a p orbital forms at the reaction center as the result of the transition from the molecular orbitals of the reactants to those of the products.
To achieve optimal orbital overlap, the nucleophile attacks 180° relative to the leaving group, resulting in the leaving group being pushed off the opposite side and the product formed with inversion of tetrahedral geometry at the central atom.
For example, the synthesis of macrocidin A, a fungal metabolite, involves an intramolecular ring closing step via an SN2 reaction with a phenoxide group as the nucleophile and a halide as the leaving group, forming an ether. Reactions such as this, with an alkoxide as the nucleophile, are known as the Williamson ether synthesis.
If the substrate that is undergoing SN2 reaction has a chiral centre, then inversion of configuration (stereochemistry and optical activity) may occur; this is called the Walden inversion. For example, 1-bromo-1-fluoroethane can undergo nucleophilic attack to form 1-fluoroethan-1-ol, with the nucleophile being an HO− group. In this case, if the reactant is levorotatory, then the product would be dextrorotatory, and vice versa.
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SN2 reaction
The bimolecular nucleophilic substitution (SN2) is a type of reaction mechanism that is common in organic chemistry. In the SN2 reaction, a strong nucleophile forms a new bond to an sp3-hybridised carbon atom via a backside attack, all while the leaving group detaches from the reaction center in a concerted (i.e. simultaneous) fashion.
The name SN2 refers to the Hughes-Ingold symbol of the mechanism: "SN" indicates that the reaction is a nucleophilic substitution, and "2" that it proceeds via a bimolecular mechanism, which means both the reacting species are involved in the rate-determining step. What distinguishes SN2 from the other major type of nucleophilic substitution, the SN1 reaction, is that the displacement of the leaving group, which is the rate-determining step, is separate from the nucleophilic attack in SN1.
The SN2 reaction can be considered as an organic-chemistry analogue of the associative substitution from the field of inorganic chemistry.
The reaction most often occurs at an aliphatic sp3 carbon center with an electronegative, stable leaving group attached to it, which is frequently a halogen (often denoted X). The formation of the C–Nu bond, due to attack by the nucleophile (denoted Nu), occurs together with the breakage of the C–X bond. The reaction occurs through a transition state in which the reaction center is pentacoordinate and approximately sp2-hybridised.
The SN2 reaction can be viewed as a HOMO–LUMO interaction between the nucleophile and substrate. The reaction occurs only when the occupied lone pair orbital of the nucleophile donates electrons to the unfilled σ* antibonding orbital between the central carbon and the leaving group. Throughout the course of the reaction, a p orbital forms at the reaction center as the result of the transition from the molecular orbitals of the reactants to those of the products.
To achieve optimal orbital overlap, the nucleophile attacks 180° relative to the leaving group, resulting in the leaving group being pushed off the opposite side and the product formed with inversion of tetrahedral geometry at the central atom.
For example, the synthesis of macrocidin A, a fungal metabolite, involves an intramolecular ring closing step via an SN2 reaction with a phenoxide group as the nucleophile and a halide as the leaving group, forming an ether. Reactions such as this, with an alkoxide as the nucleophile, are known as the Williamson ether synthesis.
If the substrate that is undergoing SN2 reaction has a chiral centre, then inversion of configuration (stereochemistry and optical activity) may occur; this is called the Walden inversion. For example, 1-bromo-1-fluoroethane can undergo nucleophilic attack to form 1-fluoroethan-1-ol, with the nucleophile being an HO− group. In this case, if the reactant is levorotatory, then the product would be dextrorotatory, and vice versa.