Substitution Reaction (SN1, SN2) - Definition, Types, Mechanism & Videos (2024)

1. Nucleophilic Substitution Reaction:

(a) What are nucleophiles?

Nucleophiles are those species in the form of an ion or a molecule which are strongly attached to the region of a positive charge. These are said to be fully charged or have negative ions present on a molecule. The common examples of nucleophiles are cyanide ions, water, hydroxide ions, and ammonia.

(b) What isNucleophilic substitution reaction?

A Nucleophilic substitution reaction in organic chemistry is a type of reaction where a nucleophile gets attached to the positive charged atoms or molecules of the other substance.

(c) Mechanism ofNucleophilic substitution reaction:

Two mechanisms of nucleophilic substitution reaction are discussed here. S_N1 reactionand theS_N2 reaction, whereSrepresents chemical substitution,Nrepresents nucleophilic, and the number stands for thekinetic orderof a reaction.

S_N2 Reaction – Mechanism of S_N2 Reaction

In this reaction, the elimination of the leaving group and the addition of the nucleophile occur simultaneously. S_N2 takes place where the central carbon atom has easy access to the nucleophile.

In S_N2 reactions, the rate of the reaction is affected by a fewconditions. They are discussed below:

• The numerical value 2 in S_N2 states that there are two concentrations of substances which affect the rate of reaction, viz. nucleophile and substrate.
• The rate equation for the above reaction is written as Rate = k [Sub][Nuc].
• Anaprotic solvent such as acetone, DMSO, or DMF is suited best for the S_N2 reaction as they do not add the H⁺ ions in the solution.
• In case if there are protons present, they react with the nucleophile to critically limit the rate of reaction. It is a one-step reaction and the reaction speed is driven by the steric effects. During the intermediate step, the position of the leaving group is inverted whereas the nucleophile is 180°.
• Nucleophilicity also affects thereaction rate.

Learn more about theSN2 reaction mechanism in detail.

S_N1 Reaction –Mechanism of S_N1 Reaction

There are certain factors that affect the S_N1reaction as well. A few are discussed below:

• Instead of two concentrations only one i.e., the substrate affects the rate of reaction.
• The rate equation for the above reaction is written as Rate = k[Sub].
• The reaction rate is determined by its slowest step. Therefore, the leaving group leaves at a particular rate which helps in determining the reaction speed.
• It is considered that the weaker the conjugate base, the better is the leaving group.
• S_N1 reactions can be determined by bulky groups that are attached to the carbocations.
• The reaction of the tertiary carbocation is faster than secondary carbocation which is faster than primary carbocation.
• The nucleophile is not required in the rate-determining step.

Learn more about theSN1 reaction mechanism in detail.

Example of Nucleophilic Substitution Reaction:

A good example of a nucleophilic substitution reaction is the hydrolysis of alkyl bromide (R-Br), under the basic conditions, wherein the nucleophile is nothing but the base OH⁻, whereas the leaving group is the Br⁻. The reaction for the following is as given below R-Br + OH⁻ →R-OH + Br⁻

Nucleophilic reactions are as important in the field of organic chemistry, and these reactions are broadly classified as to occur at the place of a carbon atom of a saturated aliphatic carbon compound.

2. Electrophilic Substitution Reactions:

(a) What are electrophiles?

The electrophilic substitution reaction involves the electrophiles. Electrophiles are those which donate a pair of electrons in the formation of a covalent bond. The Electrophilic reactions occur mostly with the aromatic compounds. These compounds have about an excess of electrons that can be shared throughout the system of reaction.

(b) What isElectrophilic substitution reaction?

The Electrophilic substitution reactions are basically defined as those chemical reactions where the electrophile replaces the functional group in a compound but not the hydrogen atom. Some examples of species of electrophiles include hydronium ion (H₃O⁺), halides of hydrogen such as HCl, HBr, HI, sulphur trioxide (SO₃), the nitronium ion (NO₂⁺), etc.

(c) Types of Electrophilic substitution reaction:

Two types of electrophilic substitution reactions are discussed here. Aromatic electrophilic substitutionreaction and aliphatic electrophilic substitution reaction.

Electrophilic Aromatic Substitution

In this type of electrophilic substitution, an atom attached to thearomatic ring which is mostly hydrogen is substituted by an electrophile. The reactions that occur arearomatic halogenation, alkylatingFriedel-Crafts reactions, aromatic nitration, and aromatic sulfonationand acylation. It further comprises acylation andalkylation.

Electrophilic Aliphatic Substitution

In this type of electrophilic substitution reaction, an electrophile dislocates one functional group.The four electrophilic aliphatic substitution reactions which are similarto counterparts of nucleophile S_N1andS_N2 are as follows – S_E1,S_E2(front),S_E2(back) and S_Ei(SubstitutionElectrophilic). During the S_E1 reaction, the substrate ionizes to acarbanion brisklyrecombines with the electrophile. During the S_E2 reaction, a singletransition state occurs where the old and newly formed bond are present.

The other types of substitution reactions include radical reactions and organometallic substitution reaction. For more details on aromatic and aliphatic electrophilic substitution checkout the Electrophilic substitution reaction mechanism.

Read more:

• SN1 and SN2 reaction of haloalkanes
• Difference between SN1 and SN2
• Difference between electrophile and nucleophile