A new functional form to study the solar wind control of the magnetopause size and shape

Abstract

In this study a new functional form, r = r₀[2/(1 + cos θ)]^α, is used to fit the size and shape of the magnetopause using crossings from ISEE 1 and 2, Active Magnetospheric Particle Tracer Explorers/Ion Release Module (AMPTE/IRM), and IMP 8 satellites. This functional form has two parameters, r₀ and α, representing the standoff distance and the level of tail flaring. The value r is the radial distance at an angle (θ) between the Sun‐Earth line and the direction of r. It is found that r₀ varies with the interplanetary magnetic field (IMF) B_z component and has a break in the slope at B_z = 0 nT. The best‐fit value of r₀ decreases with increasing southward IMF B_z. For northward IMF B_z, the best‐fit value of r₀ increases slightly with increasing B_z. The best‐fit value of α increases monotonically with decreasing IMF B_z. The dynamic pressure (D_p) also changes r₀ and α. The parameters D_p and r₀ are related by a power law of −1/(6.6±0.8). The best‐fit value of α is slightly larger for larger dynamic pressure, which implies that D_p also has a role in flux transfer from the dayside to the nightside, but the size of this effect is small. An explicit function for the size and shape of the magnetopause, in terms of D_p and B_z, is obtained by using multiple parameter fitting in a form that is useful for operational space applications such as predicting when satellites at geosynchronous orbit will be found in the magnetosheath.