In physics, the Laplace expansion of potentials that are directly proportional to the inverse of the distance (

1 / r

), such as Newton's gravitational potential or Coulomb's electrostatic potential, expresses them in terms of the spherical Legendre polynomials. In quantum mechanical calculations on atoms the expansion is used in the evaluation of integrals of the inter-electronic repulsion.

Formulation

The Laplace expansion is in fact the expansion of the inverse distance between two points. Let the points have position vectors

\textbf

and

\textbf'

, then the Laplace expansion is

\frac = \sum_^\infty \frac \sum_^ (-1)^m \frac Y^_\ell(\theta, \varphi) Y^m_\ell(\theta', \varphi').

Here

\textbf

has the spherical polar coordinates

(r, \theta, \varphi)

and

\textbf'

has

(r', \theta', \varphi')

with homogeneous polynomials of degree

\ell

. Further ''r''_< is min(''r'', ''r''′) and ''r''_> is max(''r'', ''r''′). The function

Y^m_\ell

is a normalized spherical harmonic function. The expansion takes a simpler form when written in terms of solid harmonics,

\frac = \sum_^\infty  
\sum_^\ell (-1)^m  I^_\ell(\mathbf) R^_\ell(\mathbf')\quad\text\quad \, \mathbf\,  > \, \mathbf'\, .

Derivation

The derivation of this expansion is simple. By the

law of cosines In trigonometry, the law of cosines (also known as the cosine formula or cosine rule) relates the lengths of the sides of a triangle to the cosine of one of its angles. For a triangle with sides , , and , opposite respective angles , , and (see ...

\frac = \frac =   
\frac \quad\hbox\quad h := \frac .

We find here the generating function of the

Legendre polynomials In mathematics, Legendre polynomials, named after Adrien-Marie Legendre (1782), are a system of complete and orthogonal polynomials with a wide number of mathematical properties and numerous applications. They can be defined in many ways, and t ...

P_\ell(\cos\gamma)

\frac = \sum_^\infty h^\ell P_\ell(\cos\gamma).

Use of the spherical harmonic addition theorem

P_(\cos \gamma) = \frac \sum_^\ell (-1)^m Y^_\ell(\theta, \varphi) Y^m_\ell (\theta', \varphi')

gives the desired result.

Neumann expansion

A similar equation has been derived by Carl Gottfried Neumann that allows expression of

1/r

in prolate spheroidal coordinates as a series:

\frac = \frac \sum_^\infty \sum_^\ell (-1)^m \frac \mathcal_\ell^(\sigma_) \mathcal_\ell^(\sigma_) Y_\ell^m(\arccos\tau,\varphi) Y_\ell^(\arccos\tau',\varphi')

where

\mathcal_\ell^(z)

and

\mathcal_\ell^(z)

are associated Legendre functions of the first and second kind, respectively, defined such that they are real for

z\in(1, \infty)

. In analogy to the spherical coordinate case above, the relative sizes of the radial coordinates are important, as

\sigma_=\min(\sigma, \sigma')

and

\sigma_=\max(\sigma, \sigma')

References

* {{refend Potential theory Atomic physics Rotational symmetry