S1
| - | \hbar2 |
| 2m |
\nabla2\psi=E\psi
Using polar coordinates on the 1-dimensional ring of radius R, the wave function depends only on the angular coordinate, and so[1]
\nabla2=
| 1 | |
| R2 |
| \partial2 | |
| \partial\theta2 |
Requiring that the wave function be periodic in
\theta
2\pi
| 2\pi | |
| \int | |
| 0 |
\left|\psi(\theta)\right|2d\theta=1
and
\psi(\theta)= \psi(\theta+2\pi)
Under these conditions, the solution to the Schrödinger equation is given by
\psi\pm(\theta)=
| 1 | |
| \sqrt{2\pi |
The energy eigenvalues
E
| ||||||
| e |
\theta}=
| ||||||
| e |
(\theta+2\pi)}
| ||||||
| e |
}=1=ei
The eigenfunction and eigenenergies are
\psi(\theta)=
| 1 | |
| \sqrt{2\pi |
En=
| n2\hbar2 | |
| 2mR2 |
n=0,\pm1,\pm2,\pm3,\ldots
Therefore, there are two degenerate quantum states for every value of
n>0
e\pm
The case of a particle in a one-dimensional ring is an instructive example when studying the quantization of angular momentum for, say, an electron orbiting the nucleus. The azimuthal wave functions in that case are identical to the energy eigenfunctions of the particle on a ring.
The statement that any wavefunction for the particle on a ring can be written as a superposition of energy eigenfunctions is exactly identical to the Fourier theorem about the development of any periodic function in a Fourier series.
This simple model can be used to find approximate energy levels of some ring molecules, such as benzene.
In organic chemistry, aromatic compounds contain atomic rings, such as benzene rings (the Kekulé structure) consisting of five or six, usually carbon, atoms. So does the surface of "buckyballs" (buckminsterfullerene). This ring behaves like a circular waveguide, with the valence electrons orbiting in both directions. To fill all energy levels up to n requires
2 x (2n+1)=4n+2
Further in rotational spectroscopy this model may be used as an approximation of rotational energy levels.