Before diving deep into the explanation of the Electrophilic Substitution of Benzene, let us first have a quick look at what is electrophilic substitution. In the world of chemistry, the chemical species which accept the electron pair and therefore create the bond with the nucleophiles are regarded as the electrophile. Now, when the hydrogen atom is displaced from a functional group, a molecule’s moiety causes its main chemical reactions, in a compound, this reaction is known as electrophilic substitution reaction.
In simpler terms, you can say that when the hydrogen atom is replaced by an electrophile, then such reaction is an electrophilic substitution reaction, and one such reaction is the electrophilic substitution of benzene.
Aromatic compounds are typical of electrophilic aromatic substitution reactions and are important ways of adding functional benzene ring groups. An electrophilic aliphatic substitution reaction is the other primary form of electrophilic replacement reaction.
Generally, electrophilic substitution reactions proceed through a three-step process involving the following steps.
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The appearance of an electrophile.
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The appearance of a carbocation (which is intermediate).
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The elimination from the intermediate of a proton charge.
An Overview of the Electrophilic Substitution of Benzene
Now, let us have a quick look at benzene. Benzene is a highly flammable chemical that has a sweet odour, it is either a colourless or light yellow liquid, and is found in a liquid from room temperature, which evaporates instantaneously into the air, and has the molecular formula C6H6.
Now, coming to the electrophilic substitution of benzene. Here, the hydrogen atom that is found in benzene gets substituted by the electrophile, because that is exactly what electrophilic reactions are, it displaces or substitutes the hydrogen atom. Here it substitutes the hydrogen atom of benzene. There is no fixed pattern of these reactions, it occurs randomly. Also, the aromaticity of benzene is not disrupted in the reaction.
In several of the reactions of compounds containing benzene rings – the arenas, electrophilic substitution occurs. Aromatic nitration, aromatic halogenation, aromatic sulfonation, and Friedel-Crafts reaction alkylation and acylation are some of the most important electrophilic aromatic substitutions.
What is the Electrophilic Substitution Reaction of Benzene?
As per the chemical reactivity of benzene compared to that of alkenes in the preference order to addition reactions, substitution reactions occur. These reactions are generally referred to as electrophilic aromatic substitution because the reagents and conditions used in these reactions are electrophilic. The catalysts and co-reagents are used to produce the powerful electrophilic species required to perform the initial substitution step.
Experiments have shown that substituents on a benzene ring may have a profound effect on reactivity. As determined by molecular dipole moments, this activation or deactivation of the benzene ring against electrophilic substitution can be associated with the electron-donating or electron-withdrawing effect of the substituents.
The second element that becomes important in substituted benzene reactions concerns the position at which electrophilic substitution takes place.
General Mechanism of the Electrophilic Substitution Reaction of Benzene?
A two-step process-the addition of the electrophile, followed by deprotonation-is the mechanism of electrophilic aromatic substitution.
A significant feature of this process is that if we know the product since it is the atom or group that replaces the H+, we can define the electrophile. Conversely, we can predict the product’s structure if we know the electrophile. The catalyst’s job is to bond with the leaving group and make it a better group to leave.
A more thorough study includes substitution reactions of compounds having an antagonistic orientation of substituents. The symmetry of the molecule would again simplify the decision if the substituents are similar. If a substituent has a pair of non-bonding electrons usable for adjacent charge stabilization, the product deciding power would usually be exercised.
Three steps are involved in the electrophilic substitution reaction mechanism.
Step 1: Electrophile Generation
In the generation of electrophiles from the chlorination, alkylation, and acylation of an aromatic ring, anhydrous aluminium chloride is a very helpful Lewis acid. Electrophile production takes place due to the presence of Lewis acid. The electron pair from the attacking reagent is accepted by the Lewis acid. The resulting electrophiles are Cl+, R+, and RC+O respectively (from the combination of anhydrous aluminium chloride and the attacking reagent).
Step 2: Formation of carbocation
The electrophile, forming a sigma complex or an arenium ion, attacks the aromatic ring. One of the hybridized carbons in this ion of uranium is sp3. This arenium ion, in a resonance structure, finds stability. The sigma complex or the arenium ion loses its aromatic character since the delocalization of electrons stops at the sp3 hybridized carbon.
Step 3: Deprotonation
Deprotonation is the third step of electrophilic substitution. Deprotonation is the reaction’s driving force, making it energetically possible to proceed. This step’s activation energy is much lower, and the reaction happens very rapidly.
Examples of Electrophilic Substitution Reaction
Some examples of electrophilic aromatic substitution include nitration and halogenation of benzene. The electrophiles are nitronium ion (NO2+) and sulphur trioxide (SO3), and they react with benzene individually to provide nitrobenzene and benzene sulfonic acid, respectively.
1. Benzene Sulfonation
Benzene sulfonation is a method of fuming sulphuric acid (H2SO4 + SO3) to heat benzene to create benzene-sulfonic acid. In nature, the reaction is reversible.
2. Benzene Nitration
Via the protonation of nitric acid by sulfuric acid, the source of the nitronium ion induces the loss of a water molecule and the creation of a nitronium ion.
3. Benzene Halogenation
In the presence of Lewis acid, such as FeCl3, FeBr3, Benzene reacts with halogens to form aryl halides. This reaction is known as benzene halogenation.
4. Sulfuric Acid Activation of Nitric Acid
The first step in benzene nitration is to activate HNO3 with sulfuric acid to create a nitronium ion, a stronger electrophile.