Draw the two chair conformations of each of the following substituted cyclohexanes

Draw the two chair conformations of each of the following substituted cyclohexanes. In each case, label the more stable conformation.

(a) cis-1-ethyl-2-methylcyclohexane

(b) trans-1,2-diethylcyclohexane

(c) cis-1-ethyl-4-isopropylcyclohexane

(d) trans-1-ethyl-4-methylcyclohexane

The Correct Answer and Explanation is :

To draw the two chair conformations for each substituted cyclohexane, we first need to understand how chair conformations work. Cyclohexane adopts a chair form that minimizes steric strain by placing bulky substituents in equatorial positions, which are more favorable than axial positions because axial substituents cause 1,3-diaxial interactions. The most stable conformation for a substituted cyclohexane places the larger substituents in the equatorial positions.

(a) cis-1-ethyl-2-methylcyclohexane

• Structure Explanation:
• In the cis conformation, both substituents (ethyl and methyl) are on the same side of the ring.
• For the most stable chair form, the ethyl group (larger) should occupy the equatorial position, and the methyl group (smaller) should be axial.
• The less stable chair form would have the ethyl group axial and the methyl group equatorial.
• Most stable conformation: The chair where the ethyl group is in the equatorial position and the methyl group is axial.

(b) trans-1,2-diethylcyclohexane

• Structure Explanation:
• In the trans conformation, the two ethyl groups are on opposite sides of the ring.
• For the most stable conformation, each ethyl group should be placed in the equatorial position to avoid steric hindrance.
• The less stable chair would have the ethyl groups in axial positions.
• Most stable conformation: The chair where both ethyl groups are equatorial.

(c) cis-1-ethyl-4-isopropylcyclohexane

• Structure Explanation:
• In the cis conformation, both the ethyl and isopropyl groups are on the same side of the ring.
• For the most stable conformation, the larger isopropyl group should occupy the equatorial position to reduce steric strain, while the ethyl group would be placed in the axial position.
• The less stable chair would have the ethyl group axial and the isopropyl group axial.
• Most stable conformation: The chair where the isopropyl group is equatorial, and the ethyl group is axial.

(d) trans-1-ethyl-4-methylcyclohexane

• Structure Explanation:
• In the trans conformation, the ethyl and methyl groups are on opposite sides of the ring.
• The more stable conformation places the larger ethyl group in the equatorial position, and the methyl group will be placed in the axial position.
• The less stable chair would have the ethyl group in the axial position and the methyl group in the equatorial position.
• Most stable conformation: The chair where the ethyl group is equatorial, and the methyl group is axial.

Conclusion:

In all cases, the more stable conformation is the one where bulky substituents are placed in the equatorial position. This reduces steric hindrance from 1,3-diaxial interactions, leading to a lower energy state for the molecule.