| • Science | • People | • Locations | • Timeline |
| Contents | ||
Three special cases arise, of special importance:
We outline the solutions in these cases, which should be compared to their counterparts in cartesian coordinates, cf. particle in a box. This article relies heavily on Bessel functions.
The time independent solution of 3D Schrödinger equation with hamiltonian where is the particle's mass, can be separated in the variables r, θ and φ so that the wavefunction reads:
It has the shape of the 1D Schrödinger equation for the variable , with a centrifugal term added to V, but r ranges from 0 to rather than over R.
Let us now consider V(r)=0 (if , replace everywhere E with ). Introducing the dimensionless variable
the equation becomes a Bessel equation for J defined by (whence the notational choice of J):
which regular solutions for positive energies are given by so-called Bessel functions of the first kind so that the solutions written for R are the so-called Spherical Bessel function .
The solutions of Schrödinger equation in polar coordinates for a particle of mass in vacuum are labelled by three quantum numbers: discrete indices l and m, and k varying continuously in :where , are the spherical Bessel function and are the spherical harmonics.
These solutions represent states of definite angular momentum, rather than of definite (linear) momentum, which are provided by plane waves .
Let us now consider the potential for , i.e., inside a sphere of radius and zero outside.
We first consider bound states, i.e., states which display the particle mostly inside the box (confined states). Those have an energy E less than the potential outside the sphere, i.e., they have negative energy, and we shall see that there are a discrete number of such states, which we shall compare to positive energy with a continuous spectrum, describing scattering on the sphere (of unbound states). Also worth noticing is that unlike Coulomb potential, featuring an infinite number of discrete bound states, the spherical square well has only a finite (if any) number because of its finite range (if it has finite depth).
The resolution essentially follows that of the vacuum with normalisation of the total wavefunction added, solving two Schrödinger equations—inside and outside the sphere—of the previous kind, i.e., with constant potential. Also the following constraints hold:
The first constraint comes from the fact that Neumann N and Hankel H functions are nonsingular at the origin. The physical argument that ψ must be defined everywhere selected Bessel function of the first kind J over the other possibilities in the vacuum case. For the same reason, the solution will be of this kind inside the sphere:
with A a constant to be determined later. Note that for bound states, .
Bound states bring the novelty as compared to the vacuum case that E is now negative (in the vacuum it was to be positive). This, along with third constraint, selects Hankel function of the first kind as the only converging solution at infinity (the singularity at the origin of these functions does not matter since we are now outside the sphere):
Second constraint on continuity of ψ at along with normalization allows the determination of constants A and B. Continuity of the derivative (or logarithmic derivative for convenience) requires quantization of energy.