Coulomb wave function

In mathematics, a Coulomb wave function is a solution of the Coulomb wave equation, named after Charles-Augustin de Coulomb.

They are used to describe the behavior of charged particles in a Coulomb potential and can be written in terms of confluent hypergeometric functions or Whittaker functions of imaginary argument.

The Coulomb wave equation for a single charged particle of mass

is the Schrödinger equation with Coulomb potential[1] where

is the product of the charges of the particle and of the field source (in units of the elementary charge,

for the hydrogen atom),

is the fine-structure constant, and

is the energy of the particle.

The solution, which is the Coulomb wave function, can be found by solving this equation in parabolic coordinates Depending on the boundary conditions chosen, the solution has different forms.

is the confluent hypergeometric function,

is the gamma function.

The two boundary conditions used here are which correspond to

-oriented plane-wave asymptotic states before or after its approach of the field source at the origin, respectively.

are related to each other by the formula The wave function

can be expanded into partial waves (i.e. with respect to the angular basis) to obtain angle-independent radial functions

A single term of the expansion can be isolated by the scalar product with a specific spherical harmonic The equation for single partial wave

can be obtained by rewriting the laplacian in the Coulomb wave equation in spherical coordinates and projecting the equation on a specific spherical harmonic

The solutions are also called Coulomb (partial) wave functions or spherical Coulomb functions.

changes the Coulomb wave equation into the Whittaker equation, so Coulomb wave functions can be expressed in terms of Whittaker functions with imaginary arguments

− i η , ℓ + 1

− i η , ℓ + 1

The latter can be expressed in terms of the confluent hypergeometric functions

, one defines the special solutions [4] where is called the Coulomb phase shift.

One also defines the real functions In particular one has The asymptotic behavior of the spherical Coulomb functions

correspond to incoming and outgoing spherical waves.

are real and are called the regular and irregular Coulomb wave functions.

In particular one has the following partial wave expansion for the wave function

[5] The radial parts for a given angular momentum are orthonormal.

When normalized on the wave number scale (k-scale), the continuum radial wave functions satisfy [6][7] Other common normalizations of continuum wave functions are on the reduced wave number scale (

-scale), and on the energy scale The radial wave functions defined in the previous section are normalized to as a consequence of the normalization The continuum (or scattering) Coulomb wave functions are also orthogonal to all Coulomb bound states[8] due to being eigenstates of the same hermitian operator (the hamiltonian) with different eigenvalues.