Q.18
Among heptan-1-ol, heptan-2-ol, heptan-3-ol and heptan-4-ol, compounds those exhibit optical activity are:
Optical Activity in Heptanol Isomers – Which of Heptan-1-ol, 2-ol, 3-ol and 4-ol are Chiral?
Introduction
Optical activity is an important concept in organic chemistry and stereochemistry.
A compound shows optical activity when it contains a chiral (asymmetric) carbon atom
attached to four different groups. Such molecules rotate plane polarized light.
In this problem, we must determine which of the following heptanol isomers are optically active:
- Heptan-1-ol
- Heptan-2-ol
- Heptan-3-ol
- Heptan-4-ol
Concept of Chirality
- Carbon must have four different substituents
- No plane of symmetry
- Molecule becomes optically active
Step-by-Step Solution
1️⃣ Heptan-1-ol
Structure:
CH3–(CH2)5–CH2OH
The carbon containing –OH has two identical hydrogen atoms.
❌ Not four different groups → Achiral
Result: Optically inactive
2️⃣ Heptan-2-ol
Structure:
CH3–CH(OH)–(CH2)4–CH3
Carbon is attached to:
- H
- OH
- CH3
- C5H11
✔ Four different groups → Chiral
Result: Optically active
3️⃣ Heptan-3-ol
Structure:
CH3–CH2–CH(OH)–(CH2)3–CH3
Carbon is attached to:
- H
- OH
- C2H5
- C4H9
✔ Four different groups → Chiral
Result: Optically active
4️⃣ Heptan-4-ol
Structure:
CH3–CH2–CH2–CH(OH)–CH2–CH2–CH3
Two identical propyl groups are present on both sides of the carbon.
Identical substituents → Plane of symmetry → Achiral
Result: Optically inactive
Final Answer
Optically active compounds: Heptan-2-ol and Heptan-3-ol
✔ Correct Option: (A)
Quick Comparison Table
| Compound | Chiral Carbon | Optical Activity |
|---|---|---|
| Heptan-1-ol | ❌ No | Inactive |
| Heptan-2-ol | ✔ Yes | Active |
| Heptan-3-ol | ✔ Yes | Active |
| Heptan-4-ol | ❌ No | Inactive |
Exam Tips
- Terminal alcohols are usually achiral
- Check for identical groups carefully
- Always verify four different substituents
