Use strain energy increments in the OWL Table Reference (see References button, Strain Energy Increments) to calculate the energy difference between the two chair conformations of the compound below. Specify substituent positions (axial or equatorial) in the more stable chair. Estimate the percent of the more stable chair at equilibrium at 25°C. (To determine the percent of the more stable chair at equilibrium, first calculate Keq, and then use this value to find the percentage.) Answers: The energy difference is kJ/mol. In the more stable chair: The methyl group is in the position. The hydroxyl group is in the position. At 25°C the equilibrium percent of the more stable chair conformation is approximately .

The cyclohexane derivative shown exists primarily in the morestable of the two available chair conformations. Give the position,axial or equatorial, of each of the three groups shown in the morestable chair conformation. If a group divides its time equallybetween axial and equatorial positions, indicate this withax/eq.

The table of "Axial Strain Energies for MonosubstitutedCyclohexanes" found in the "Strain Energy Increments" section ofthe Reference tool is useful for answering thisquestion.

The choices are axial, equatorial, orboth.

a)

b)

c)

First correct answer gets points.

The cyclohexane derivative shown exists primarily in the morestable of the two available chair conformations. Give the position,axial or equatorial, of each of the three groups shown in the morestable chair conformation. If a group divides its time equallybetween axial and equatorial positions, indicate this withax/eq.

The table of "Axial Strain Energies for MonosubstitutedCyclohexanes" found in the "Strain Energy Increments" section ofthe Reference tool is useful for answering thisquestion.

The choices are axial, equatorial, or both.

a)

b)

c)

First correct answer gets points.