The energy of rotation about a single bond is a periodic function of the torsion angle, ? , and is, therefore, appropriately described in terms of a truncated Fourier series, the simplest acceptable form of which is given by
Here, V1 is the onefold component (periodic in 360° ), V2 is the twofold component (periodic in 180° ) and V3 is the threefold component (periodic in 180° ).
A Fourier series is an example of an orthogonal polynomial, meaning that the individual terms which it comprises are independent of each other. It should be possible, therefore, to dissect a complex rotational energy profile into a series of N-fold components and to interpret each of these components independent of all others. The one-fold component is quite easy to rationalize. For example, the onefold term for rotation about the central bond in n-butane no doubt reflects the crowding of methyl groups,
whereas the onefold term in 1,2-difluoroethane probably reflects differences in electrostatic interactions as represented by bond dipoles:
The threefold component represents the difference in energy between eclipsed and staggered arrangements about a single bond. However, the twofold component is perhaps the most interesting of the three and is what concerns us here. It relates to the difference in energy between planar and perpendicular arrangements.
Optimize the geometry of dimethyl peroxide (CH3OOCH3) subject to the COOC dihedral angle being held at 0°, 20°, 40° ,180° (10 optimizations in total). Use the B3LYP/6-31G* density functional model. Construct a plot of energy versus dihedral angle and fit this to a three-term Fourier series. Does the Fourier series provide a good fit to your data? If so, what is the dominant term? Rationalize it. What is the second most important term? Rationalize your result.
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