Why are aryl halides less reactive towards nucleophilic substitution reactions as compared to alkyl halides * 2 points?

Explain. Aryl halides are less reactive than alkyl halides towards nucleophilic substitution reactions.

1. The low reactivity of aryl halides is due to the resonance effect and sp2 hybrid state of carbon to which halogen atom is attached.
2. In aryl halides, one of the lone pairs of electrons on the halogen atom is in conjugation with π-electrons of the ring. Due to resonance, the C–X bond acquires partial double bond character. Thus, the C–X bond in aryl halides is stronger and shorter than alkyl halides. Hence, it is difficult to break C–X bond in aryl halides.
3. Further, the phenyl cation produced due to the self-ionization of aryl halide will not be stabilised by resonance. This rules out the possibility of SN1 mechanism. Also, the backside attack of nucleophiles is blocked by the aromatic ring. This rules out the possibility of SN2 mechanism. As a result, nucleophilic substitution reaction involving cleavage of C–X bond in haloarenes proceeds with difficulty.
4. Therefore, aryl halides are less reactive than alkyl halides towards nucleophilic substitution reactions.

Concept: Chemical Properties

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Aryl halides are less reactive towards nucleophilic substitution reaction as compared to alkyl halide due to

The formation of less stable carbene

Longer carbon halogen bond

$s{p}^2$ -hybridised carbon bonded to halogen

Text Solution

The formation of less stable carbonium ionResonance stabilizationLonger carbon halogen bond `sp^(2)`-hybridized carbon attached to the halogen

Answer : B::D

Solution : Aryl halide are less reactive towards nucleophilic substitution reaction as compared to alkyl halide due to following reason, (b) resonance stabilization <br> (e) `sp^(2)`-hybridized carbon attached to the halogen. <br> <img src="https://d10lpgp6xz60nq.cloudfront.net/physics_images/ERRL_CHM_V02_C22_E03_035_S01.png" width="80%">.