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Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry PDF Download

Monosubstituted cyclohexane:-

1. When methyl group is axial it is sufficient ly closer to the Syn axial Hydrogen’s to undergo 1,3-diaxial interactions and is repelled by them ( This is another example of trans-annular strain)

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

2. This 1, 3-diaxial interact ion is similar to that in gauche conformat ion o f butane. The axial methyl group in methyl cyclohexane is thus gauche to two ring carbons and when in equatorial positions it is anti to same nuclei.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

3. When methyl group is equatorial, there are no 1, 3-diaxial interaction.

4. Equatorial methyl group don’t show any gauche butane like interactions.
Monosubstituted cyclohexane exists in two non-equivalent diastereomeric chair conformations.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

I) is less stable than (ii) because of the presence of 1, 3-diaxial interactions.

Disubstituted cyclohexane

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry
Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

Stability:- A > C=D > B

Enantiomerism in 1, 2-dimethyl cyclohexane: - In 1, 2-dimethylcyclohexane two chiral centers are present and hence can have more than four stereoisomers but actually it has only three. The Cis-1, 2-dimethylcyclohexane molecule is not superimposable on its mirror image but the molecule and its mirror  image are readily interconvertible by flipping one chair conformation into another. Hence these are conformational enantiomers. There is a rapid Interconversion at room temperature.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

                                      Axial-equatorial cis-1, 2-dimethylcyclohexane 

The trans-1, 2-dimethylcyclohexane molecule and its mirror image are not superimposable, hence constitute an enantiomeric pair. These are not interconvertible by flipping one chair form into another. On flipping the equatorial is converted into axial. The two isomers are known as configurational isomers. Each isomer is optically active and mixture is resolvable. 

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

                            Trans -1, 2-dimethylcyclohexane 

In summary 1, 2-dimethylcyclohexane exists as a pair of Diastereomers, the Cis and trans isomers. The Cis isomer exists as a pair of conformational enantiomer, whereas the trans isomer exists as a pair of configuration Diastereomers.

Chirality and optically activity 
All 1, 2-disubstitutedcyclohexanes are achiral due to presence of plane of symmetry and two fold rotational axis hence all are optically inactive.

1, 3-disubstitutedcyclohexane

 Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

Stability: - A>C=B>D

1, 3-dimethylcyclo hexane has two chiral centers, and can have  four stereoiso mers (22=4). Actually there are only three, the cis-1, 3-dimethylcyclohexane has a plane of symmetry and is achiral. Trans isomer has a twofold rotational axis hence it is also achiral. If different substituents are present all will be chiral. 

1, 4-disubstututedcyclohexane

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry
Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

Stability: - A > C = D > B

In 1, 4-dimethylcyclohexane it does not have any chiral centre. It exists as Cis and Trans Diastereomers. Neither Cis nor Trans form is chiral because both have a plane of symmetry.
 

Chirality:- All are achiral due to the plane of symmetry If different substituent’s then all 1, 4-disubstituted will be chiral.

Factors affecting stability of cyclohexane derivatives

1. Steric strain α 1/ stability
2. Torisonal strain α 1/ stability

3. Dipole moment:- If µ > 0 less stable, If µ=0 more stable If electronegative group is present then 1,2-diaxial is more stable than 1,2-diequatorial due to dipoledipole repulsions.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

4. Hydrogen bonding:- In cases where  hydrogen bonding is possible, gauche form is more stable than the staggered form as in case of ethylene glycol.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

Stable conformations of cyclohexandiols 

A. 1,4-diol :-

Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry
B. 1,2-diols:-

Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

C. 1,3-diols:-
Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry


Problem:- Draw the most stable chair conformation of following cyclohexanes

 Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry
Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

 

Decalins- bicyclo[4,4,0]decane

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

Trans- decalin:

Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry
Trans decalin is obtained by fusion between two equatorial bonds of cyclohexanes with 4 carbon system. In this two hydrogen atoms on the bridge head carbon are opposite to each other. Achiral, more stable due to diequatorial type structure.


Cis-decalin :

When one axial and one equatorial bond of cyclohexanes ring are used for fusing 4 carbon chain system a decalin molecule results which has two hydrogen on the same side of bridgehead carbon.

 Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

(i) Less stable due to non-bonding interactions
(ii) No plane of symmetry
(iii) Molecule is chiral

Cis- and trans- isomers are conformational isomers. Energy of trans decalin is 25 kj/mol lesser than cis decalins

Stability Trans decalins are generally more stable. If 1 position of decalin is substituted by Me- group then stabilit y is reversed 

 Conformations of Mono & Disubstituted Cyclohexanes | Organic ChemistryConformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry

The document Conformations of Mono & Disubstituted Cyclohexanes | Organic Chemistry is a part of the Chemistry Course Organic Chemistry.
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FAQs on Conformations of Mono & Disubstituted Cyclohexanes - Organic Chemistry

1. What is the conformation of a mono-substituted cyclohexane?
Ans. In a mono-substituted cyclohexane, the substituent can adopt two different conformations: axial and equatorial. The axial conformation occurs when the substituent is pointing straight up or down from the cyclohexane ring, while the equatorial conformation occurs when the substituent is pointing outward from the ring in a horizontal direction.
2. How does the conformation of a mono-substituted cyclohexane affect its stability?
Ans. The conformation of a mono-substituted cyclohexane can significantly affect its stability. Generally, the equatorial conformation is more stable than the axial conformation. This is because the axial conformation experiences steric hindrance between the substituent and neighboring hydrogen atoms, leading to higher energy levels. In contrast, the equatorial conformation avoids this steric hindrance and achieves a lower energy state.
3. What are the different conformations of a disubstituted cyclohexane?
Ans. A disubstituted cyclohexane can have three different conformations: cis, trans, and axial-equatorial. The cis conformation occurs when both substituents are on the same side of the ring, the trans conformation occurs when they are on opposite sides, and the axial-equatorial conformation occurs when one substituent is in the axial position and the other is in the equatorial position.
4. How does the conformation of a disubstituted cyclohexane affect its stability?
Ans. The conformation of a disubstituted cyclohexane can greatly impact its stability. Generally, the trans conformation is more stable than the cis conformation. This is because the cis conformation experiences steric hindrance between the two substituents, leading to higher energy levels. In contrast, the trans conformation avoids this steric hindrance and achieves a lower energy state. Additionally, if one substituent is in the axial position and the other in the equatorial position, the conformation will be more stable due to the reduced steric interaction between the substituents.
5. How can we determine the most stable conformation of a substituted cyclohexane?
Ans. The most stable conformation of a substituted cyclohexane can be determined by considering the factors that affect stability, such as steric hindrance and favorable interactions. In general, the conformation with the least steric hindrance and the most favorable interactions will be the most stable. For mono-substituted cyclohexanes, the equatorial conformation is often more stable due to reduced steric hindrance. For disubstituted cyclohexanes, the trans conformation is typically more stable due to avoiding steric hindrance between the substituents. However, it is important to consider other factors such as electronic effects and specific interactions between the substituents and the ring.
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