AUTHOR=Denton Richard E. , Takahashi Kazue , Min Kyungguk , Hartley David P. , Nishimura Yukitoshi , Digman Matthew C. TITLE=Models for magnetospheric mass density and average ion mass including radial dependence JOURNAL=Frontiers in Astronomy and Space Sciences VOLUME=9 YEAR=2022 URL=https://www.frontiersin.org/journals/astronomy-and-space-sciences/articles/10.3389/fspas.2022.1049684 DOI=10.3389/fspas.2022.1049684 ISSN=2296-987X ABSTRACT=

Analytical models for magnetospheric mass density, ρ_m, and average ion mass, M, were created from a database of ρ_m and electron density, n_e, values from six spacecraft missions by making use of the Eureqa nonlinear genetic regression algorithm. All values of ρ_m were determined from Alfvén frequencies, and the values of n_e were determined from plasma wave or spacecraft potential data. Models of varying complexity are listed. The most complex models appearing in this paper are capable of modeling ρ_m within a factor of 1.81, and M within a factor of 1.34 if n_e is used as an input parameter, or within a factor of 1.45 if n_e is not used. The most important parameters for modeling ρ_m are L, the solar EUV index F10.7, magnetic local time, MLT, the geomagnetic activity index Kp, and the solar wind dynamic pressure, Pdyn. The very simplest model for M depends on Kp. In more complex models for M including n_e, the most important parameters are n_e with L, F10.7, and Pdyn or Kp. In more complex models for M not including n_e, the most important parameters are Kp, MLT, F10.7, L, and the auroral electrojet index, AE. Explanations for most of the dependencies are given. We also demonstrate the danger of calculating spatial dependence without taking account of different conditions sampled in different regions. Here we avoid that problem by using multivariant models.