I = mr²

The rotation of three-dimensional objects like molecules can be quite complicated but as they can be considered to be made up from collections of point masses (or atoms), the above relationship can be used to work out the overall moment of inertia for any molecule. The dependence of I on r leads to one of the major reasons for studying molecular rotations - working out highly accurate bond lengths.

It is convenient to break the rotations down into those about three mutually perpendicular directions, called the principal axes of rotation. Each molecule therefore has three moments of inertia corresponding to the resistance to rotation about these axes. The three moments are usually labelled I_A, I_B and I_C. Because of molecular shapes and symmetries, some of these moments may be zero or may be the same. It is therefore convenient to group molecules according to the relationship between the moments.

Linear molecules

Linear molecules such as HCl, HCCH and CO₂ can rotate in three ways:

• The two types of end-over-end rotation are equally difficult (rotate the molecule to show this) so I_B = I_C.
• Rotation about the bond axis takes no energy so I_A = 0.

Follow the links below for more information on the energy levels and rotational spectroscopy of linear molecules:

1. energy levels:
   • rigid rotor,
   • non-rigid rotor.
2. microwave spectrum:
   • rigid rotor,
   • non-rigid rotor.
3. intensity of microwave lines:
   • population of rotational levels,
   • intensity of lines