Note that these states would have a definite parity ifx= 0 were at the center of the box.
Theexpansionof an arbitrary wave function in these eigenfunctions is essentially ouroriginal
Fourier Series. This is a good example of the energy eigenfunctions being orthogonal and covering
the space.
8.5.1 The Same Problem with Parity Symmetry
If we simplyredefine the position of the boxso that−a 2 < x < a 2 , then our problem has
symmetry under the Parity operation.
x→−xThe Hamiltonian remains unchanged if we make the above transformation. The Hamiltonian com-
mutes with the Parity operator.
[H,P] = 0
This means that (Pui) is an eigenfunction ofHwith the same energy eigenvalue.
H(Pui) =P(Hui) =PEiui=Ei(Pui)Thus, it must be a constant times the same energy eigenfunction.
Pui=cuiThe equations says theenergy eigenfunctions are also eigenfunctions of the parity operator.
If we operate twice with parity, we get back to the original function,
P^2 ui=uiso theparity eigenvalues must be± 1.
Pui=± 1 uiThe boundary conditions are
ψ(±
a
2) = 0.
This givestwo types of solutions.
u+n(x) =√
2
acos(
(2n−1)πx
a)
u−n(x) =√
2
asin(
2 nπx
a)
E+n = (2n−1)^2
π^2 ̄h^2
2 ma^2En− = (2n)^2π^2 ̄h^2
2 ma^2