Unit 5: Alkyl and Aryl Halides

Course Code: CHM-DSM-252

Paper Name: Fundamentals of Chemistry - II

1. Alkyl Halides: Preparation and Mechanisms
2. Types of Nucleophilic Substitution (SN1, SN2, SNi)
3. Williamson’s Ether Synthesis & Elimination
4. Aryl Halides: Synthesis and Reactions
5. Benzyne Mechanism
6. Reactivity and Bond Strength Comparisons
7. Exam Focus: Tips and FAQs

1. Alkyl Halides: Preparation and Mechanisms

Alkyl halides (haloalkanes) are compounds where one or more hydrogen atoms in an alkane have been replaced by halogen atoms.

Methods of Preparation

From Alkenes: Addition of hydrogen halides (HX) following Markownikoff's or anti-Markownikoff's rules.
From Alcohols: Reaction with HX, PX3, PX5, or SOCl2.

2. Types of Nucleophilic Substitution

The reactivity of alkyl halides is dominated by nucleophilic substitution reactions.

Mechanism	Kinetics	Stereochemistry	Preferred Substrate
SN1	Unimolecular (First order)	Racemization	Tertiary (3°) halides
SN2	Bimolecular (Second order)	Inversion (Walden Inversion)	Primary (1°) halides
SNi	Internal Nucleophilic Substitution	Retention of configuration	Alcohols + SOCl2

3. Williamson’s Ether Synthesis & Elimination

This is an important method for the preparation of symmetrical and unsymmetrical ethers.

Reaction: An alkyl halide reacts with a sodium alkoxide (R-ONa).
Competition: Elimination reactions often compete with substitution, especially with secondary and tertiary halides or at higher temperatures.

4. Aryl Halides: Synthesis and Reactions

Aryl halides are compounds where the halogen is directly attached to an aromatic ring.

Preparation Methods

From Phenol: Replacement of the -OH group, though less common than in alcohols.
Sandmeyer and Gattermann Reactions: Starting from diazonium salts to produce chloro, bromo, and iodo-benzene.

5. Benzyne Mechanism

Aryl halides are generally unreactive toward nucleophilic substitution but can react under vigorous conditions via the Benzyne Mechanism.

Reagents: Use of very strong bases like KNH2/NH3 or NaNH2/NH3.
Intermediate: Formation of a highly reactive "benzyne" intermediate (a benzene ring with a formal triple bond).

6. Reactivity and Bond Strength Comparisons

The strength of the Carbon-Halogen (C-X) bond varies significantly across different types of halides.

Aryl and Vinyl Halides: These are less reactive toward nucleophilic substitution due to the partial double-bond character of the C-X bond (resonance).
Alkyl, Allyl, and Benzyl Halides: Allyl and benzyl halides are exceptionally reactive in SN1 reactions because the resulting carbocations are stabilized by resonance.

7. Exam Focus: Tips and FAQs

Exam Tips:

Stereochemistry: Always specify "Inversion" for SN2 and "Racemization" for SN1 in descriptive answers.
Effect of Substituents: Remember that electron-withdrawing groups (like -NO2) at ortho and para positions significantly increase the reactivity of aryl halides toward nucleophilic substitution.
Mechanism Identification: Primary halides + strong nucleophiles usually follow SN2; Tertiary halides + polar protic solvents follow SN1.

Frequently Asked Questions

Q: Why are aryl halides less reactive than alkyl halides toward nucleophilic substitution?
A: Due to the resonance effect which gives the C-X bond partial double-bond character, making it shorter and stronger.

Q: What is the Walden Inversion?
A: It is the inversion of optical configuration that occurs during an SN2 reaction.

Q: When does elimination predominate over substitution?
A: With bulky bases, tertiary substrates, or at elevated temperatures.