15.7 Isomerism

Organic molecules exhibit isomerism due to the directional nature of their covalent bonds. Isomers are molecules that share the same molecular formula but have different structural formulas. The phenomenon itself is called isomerism.

Isomerism is a primary reason for the vast number of organic compounds. As the number of carbon atoms in a molecule increases, the number of possible isomers grows exponentially. For example, butane ($C_4{H}_{10}$) has two isomers, while decane ($C_{10}{H}_{22}$) has 75 isomers.

Isomerism is broadly classified into two types:

1. Structural Isomerism
2. Stereoisomerism (including geometric isomerism)

This section will focus on structural isomerism.

Structural Isomerism

Structural isomers are compounds that have the same molecular formula but a different arrangement of atoms (i.e., a different structural formula). Structural isomerism arises from the property of catenation which allows carbon atoms to form chains and branches of varying lengths and shapes. There are five main types of structural isomerism.

i. Chain Isomerism

Chain isomerism occurs when compounds have the same molecular formula but differ in the structure of their carbon chains (e.g., straight-chain vs. branched-chain). The nomenclature of aliphatic organic compounds distinguishes these isomers using prefixes like n-, iso-, and neo-.

Example: Isomers of Butane ($C_4{H}_{10}$)

• Butane (n-butane): A straight-chain alkane. $H_{3}C-C{H}_2-C{H}_2-C{H}_3$

• 2-methylpropane (isobutane): A branched-chain alkane. $\begin{array}{c}C{H}_3\\ |\\ H_{3}C-CH-C{H}_3\end{array}$

ii. Positional Isomerism

Positional isomers are compounds with the same molecular formula and the same carbon skeleton but differ in the position of a functional group on the carbon chain. The functional group remains identical, but its location changes.

Example: Isomers of Chloropropane ($C_3{H}_{7}Cl$)

• 1-chloropropane: The chlorine atom is on the first carbon. $H_{3}C-C{H}_2-C{H}_2-Cl$

• 2-chloropropane: The chlorine atom is on the second carbon. $\begin{array}{c}Cl\\ |\\ H_{3}C-CH-C{H}_3\end{array}$

iii. Functional Group Isomerism

Functional group isomerism arises when compounds have the same molecular formula but contain different functional groups. This leads to the isomers belonging to different families of organic compounds.

Example: Isomers with the formula $C_2{H}_{6}O$

• Ethanol: An alcohol with a hydroxyl (-OH) group. $H_{3}C-C{H}_2-OH$

• Methoxymethane (Dimethyl ether): An ether with an ether (-O-) linkage. $H_{3}C-O-C{H}_3$

iv. Metamerism

Metamerism is a type of isomerism where compounds have the same molecular formula and the same functional group, but differ in the length of the carbon chains on either side of the functional group. This is common in ethers, ketones, and secondary amines.

Example: Isomers with the formula $C_4{H}_{10}O$ (Ethers)

• Ethoxyethane (Diethyl ether): Two ethyl groups attached to the oxygen. $H_{3}C-C{H}_2-O-C{H}_2-C{H}_3$

• Methoxypropane: A methyl group and a propyl group attached to the oxygen. $H_{3}C-O-C{H}_2-C{H}_2-C{H}_3$

v. Tautomerism

Tautomerism is a special type of isomerism where two isomers, called tautomers, are in dynamic equilibrium with each other. The isomers differ in the position of a proton (hydrogen atom) and a double bond. This typically involves the migration of a proton from one atom to another within the molecule.

Keto-Enol Tautomerism: A common example where one tautomer is a ketone (keto form) and the other is an enol (containing a C=C double bond and an -OH group).

Example: Ethyl acetoacetate

• The keto form and the enol form exist in a dynamic equilibrium.

$\underset{\text{Keto form (major)}}{\underbrace{\begin{array}{ccc}O& & O\\ ||& & ||\\ C{H}_3-C& -& C{H}_2-C-O{C}_2{H}_5\end{array}}}\rightleftharpoons \underset{\text{Enol form (minor)}}{\underbrace{\begin{array}{ccc}OH& & O\\ |& & ||\\ C{H}_3-C& =& CH-C-O{C}_2{H}_5\end{array}}}$

Worked Examples

Q1: Draw the structural formulae of the possible structural isomers of:

• i. Pentane ($C_5{H}_{12}$)
• ii. Propan-1-ol ($C_3{H}_{8}O$)

A1:

i. Isomers of Pentane ($C_5{H}_{12}$): These are chain isomers.

1. n-pentane: $H_{3}C-C{H}_2-C{H}_2-C{H}_2-C{H}_3$

2. Isopentane (2-methylbutane): $\begin{array}{c}C{H}_3\\ |\\ H_{3}C-CH-C{H}_2-C{H}_3\end{array}$

3. Neopentane (2,2-dimethylpropane): $\begin{array}{c}C{H}_3\\ |\\ H_{3}C-C-C{H}_3\\ |\\ C{H}_3\end{array}$

ii. Isomers of Propan-1-ol ($C_3{H}_{8}O$):

1. Propan-1-ol: (The original molecule) $H_{3}C-C{H}_2-C{H}_2-OH$

2. Propan-2-ol: (Positional isomer) $\begin{array}{c}OH\\ |\\ H_{3}C-CH-C{H}_3\end{array}$

3. Methoxyethane: (Functional group isomer — an ether) $H_{3}C-C{H}_2-O-C{H}_3$

Q2: Examine the concept of isomerism in organic compounds.

A2: Isomerism describes the existence of molecules that have the same molecular formula but differ in the arrangement of their atoms. This difference in structure leads to different physical and chemical properties. Structural isomerism, a major type, includes five subtypes:

• Chain isomerism: Different carbon skeleton arrangements (straight vs. branched).
• Positional isomerism: Same skeleton and functional group, but the functional group is at a different position.
• Functional group isomerism: Same molecular formula but different functional groups, placing compounds in different homologous series.
• Metamerism: Same functional group but different alkyl chain lengths on either side of it.
• Tautomerism: A dynamic equilibrium between two interconverting isomers (tautomers) involving proton migration and double bond shift, e.g., keto-enol tautomerism.

Isomerism is a key reason for the enormous diversity of organic compounds.