Dipole model of the Earth's magnetic field

Plot showing field lines (which, in three dimensions would describe "shells") for L-values 1.5, 2, 3, 4 and 5 using a dipole model of the Earth's magnetic field

The dipole model of the Earth's magnetic field is a first order approximation of the rather complex true Earth's magnetic field. Due to effects of the interplanetary magnetic field, and the solar wind, the dipole model is particularly inaccurate at high L-shells (e.g., above L=3), but may be a good approximation for lower L-shells. For more precise work, or for any work at higher L-shells, a more accurate model that incorporates solar effects, such as the Tsyganenko magnetic field model, is recommended.

Equations

The following equations describe the dipole magnetic field.^[1]

First, define $B_0$ as the mean value of the magnetic field at the magnetic equator on the Earth's surface. Typically $B_0=3.12\times10^{-5}\ \textrm{T}$ .

Then, the radial and azimuthal fields can be described as

$B_r = -2B_0\left(\frac{R_E}{r}\right)^3\cos\theta$

$B_\theta = -B_0\left(\frac{R_E}{r}\right)^3\sin\theta$

$|B| = B_0\left(\frac{R_E}{r}\right)^3 \sqrt{1 + 3\cos^2\theta}$

where $R_E$ is the mean radius of the Earth (approximately 6370 km), $r$ is the radial distance from the center of the Earth (using the same units as used for $R_E$ ), and $\theta$ is the azimuth measured from the north magnetic pole.

It is sometimes more convenient to express the magnetic field in terms of magnetic latitude and distance in earth radii. The magnetic latitude $\lambda$ is measured northwards from the equator (analogous to geographic latitude) and is related to $\theta$ by $\lambda = \pi/2 - \theta$ . In this case, the radial and azimuthal components of the magnetic field (the latter still in the $\theta$ direction, measured from the axis of the north pole) are given by