Laplace expansion (potential): Difference between revisions

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imported>Paul Wormer
(Small modification of my Wiki text.)
 
imported>Paul Wormer
Line 19: Line 19:
(-1)^m  I^{-m}_\ell(\mathbf{r}) R^{m}_\ell(\mathbf{r}')\quad\hbox{with}\quad |\mathbf{r}| > |\mathbf{r}'|,
(-1)^m  I^{-m}_\ell(\mathbf{r}) R^{m}_\ell(\mathbf{r}')\quad\hbox{with}\quad |\mathbf{r}| > |\mathbf{r}'|,
</math>
</math>
where <math>I^{m}_\ell</math> is an irregular solid harmonic and <math>R^{m}_\ell</math> s a regular solid harmonic.
where <math>I^{m}_\ell</math> is an irregular solid harmonic and <math>R^{m}_\ell</math> is a regular solid harmonic.
 
==Derivation==
==Derivation==
The derivation of this expansion is simple. One writes
The derivation of this expansion is simple. One writes

Revision as of 05:27, 20 August 2007

In physics, the Laplace expansion of a 1/r - type potential is applied to expand Newton's gravitational potential or Coulomb's electrostatic potential. In quantum mechanical calculations on atoms the expansion is used in the evaluation of integrals of the interelectronic repulsion.

The expansion

The Laplace expansion is in fact the expansion of the inverse distance between two points. Let the points have position vectors r and r', then the Laplace expansion is

Here r has the spherical polar coordinates (r, θ, φ) and r' has ( r', θ', φ'). Further r< is min(r, r') and r> is max(r, r'). The function is a normalized spherical harmonic function. The expansion takes a simpler form when written in terms of solid harmonics,

where is an irregular solid harmonic and is a regular solid harmonic.

Derivation

The derivation of this expansion is simple. One writes

We find here the generating function of the Legendre polynomials  :

Use of the spherical harmonic addition theorem

gives the desired result.