The ring flip of
cyclohexane does one very significant thing: it exchanges axial
and equatorial positions. Compare the two structures below and
make a model that has some identification to distinguish axial and
equatorial positions.
For cyclohexane itself, this does not make much difference. On the other hand, when there is a substituent like a methyl group, it makes a big difference, because the structural relationship between the methyl group and other parts of the molecule changes:
The energy difference, 1.8 kcal/mol, arises from the 1,3 diaxial interactions between the methyl hydrogens and the other axial hydrogens. This is greater than the interactions with flanking equatorial hydrogens in the equatorial conformer. The energetic cost of these 1,3-diaxial interactions is general, and varies according to the bulk of the group (and to a smaller extent, the polarity of the bond). The cost of placing a group axial is called the "A value" and represents ΔG° between axial and equatorial forms.
For an exhaustive list of A values, see Wikipedia. Try making models of cyclohexane with different substituents and make sure you can locate the axial-axial interactions and make sense of the table shown here. Viewing as "Spacefilling" highlights the true steric demand of each substituent. |