Conformations of Acyclic systems

Question 1

What is ring strain energy?

Answer 1

• The ‘extra’ energy a molecule has by virtue of being constrained to a ring
• Determined from heats of combustion

Question 2

How many carbons are there in small rings

Answer 2

Between 3-4 carbons

Question 3

How many carbons are there in normal sized rings

Answer 3

between 5-7 carbons

Question 4

What happens to the ring strain energy as the ring gets bigger?

Answer 4

(apart from normal rings) the smaller the ring the larger the ring strain energy

Question 5

How many carbons are in medium sized rings

Answer 5

8-14

Question 6

How many carbons are in large rings?

Answer 6

> 14

Question 7

What are the 4 contributions to conformational energy in acyclic compounds?

Answer 7

• Sterics (repulsion between substituents)
• Pitzer strain (repulsion between electrons in filled orbitals - favours staggered)
• Hyperconjugation (σ-σ’ overlap stabilises staggered)
• Hydrogen bonding

Question 8

The conformation energier of saturated rings are determined by all the factors which affect acyclic systems and….

Answer 8

• Baeyer Strain
• Transannual Strain

Question 9

What is Baeyer Strain?

Answer 9

Atoms are distorted from their ideal bond angles in order to form a ring (required energy to distort)
(e.g. from a 109.5° to 60°)

Question 10

What is Transannular strain?

Answer 10

• Subsituents pointing at each other across the ring, leading to additional steric strain
• Effects medium rings only (8-14 C)
• e.g the 3 groups (in red) are pushed towards the centre of the molecule resulting in higher energy)

Question 11

In general, rings will adopt the lowest energy (most stable) conformation possible by…

Answer 11

…minimising Baeyer (angle) and Pitzer (torsional) strain)

Question 12

How does a compound facilitate the move from a 109.5° bond angle to a 60° bond angle in a cyclic compound?

Answer 12

• Results in these round ‘banna bonds’ due to distortion
• To allow this the carbon atoms rehybridize, forming sp›³ (more p character)
• Results in overall weaker bonds

Question 13

Why is the Pitzer strain so high in cyclopropane?

Answer 13

• All of the C-atoms are in one plane
• all C-C bonds are eclipsed
• Hence resulting in high Pitzer strain

Question 14

Cyclobutane rings puckers to reduce their overall energy (folding of the ring shown in the image)
What does this does to the Baeyer strain?

Answer 14

• Puckering decreases the bond angles
• Hence increased Baeyer strain

Question 15

How will cyclopentane pucker to adopt the lowest energy conformation?

Answer 15

• Envelope conformation
• Some Pitzer strain
• Some Baeyer strain

Question 16

Cyclobutane ring puckers to reduce their overall energy
What affect does this have on Pitzer strain

Answer 16

• No bonds are fully eclipsed
• Reduced (but still high) Pitzer energy

Question 17

How will cyclohexane pucker to adopt the lowest energy conformation?

Answer 17

• Chair conformation
• All bonds are staggered
• Essentially strain free

Question 18

Cyclohexane adopts a chair conformation to minisize Baeyer strain and Pitzer strain
What other conformers can it form however?

Answer 18

Question 19

Substituted cyclohexanes generally favour the chair conformation that puts the largest group in…

Answer 19

Equatorial in order to minimise 1,3-diaxial interactions

Question 20

What is an A-value?

Answer 20

• The Energy difference between the lowest energy conformation and the highest energy conformation
• The higher A, the bigger the substituent