# Defining and resolving current systems in geospace

**Authors:** N. Y. Ganushkina, M. W. Liemohn, S. Dubyagin, I. A. Daglis, I., Dandouras, D. L. De Zeeuw, Y. Ebihara, R. Ilie, R. Katus, M. Kubyshkina, S., E. Milan, S. Ohtani, N. Ostgaard, J. P. Reistad, P. Tenfjord, F. Toffoletto,, S. Zaharia, and O. Amariutei

arXiv: 1701.04714 · 2017-01-18

## TL;DR

This paper reviews and compares various definitions and identification methods of current systems in near-Earth geospace, highlighting how definitional choices impact understanding of magnetospheric dynamics.

## Contribution

It provides a comprehensive collection of current system definitions and analyzes how different methods influence interpretation of geospace physical processes.

## Key findings

- Multiple current systems exist in near-Earth magnetosphere.
- Definitional choices significantly affect physical process interpretation.
- Various observational and computational techniques are used for identification.

## Abstract

Electric currents flowing through near-Earth space ($\textit{R}$ $\leq$12 $\mathit{R}_{E}$) can support a highly distorted magnetic field topology, changing particle drift paths and therefore having a nonlinear feedback on the currents themselves. A number of current systems exist in the magnetosphere, most commonly defined as (1) the dayside magnetopause Chapman-Ferraro currents, (2) the Birkeland field-aligned currents with high latitude "region 1" and lower-latitude "region 2" currents connected to the partial ring current, (3) the magnetotail currents, and (4) the symmetric ring current. In the near-Earth nightside region, however, several of these current systems flow in close proximity to each other. Moreover, the existence of other temporal current systems, such as the substorm current wedge or "banana" current, has been reported. It is very difficult to identify a local measurement as belonging to a specific system. Such identification is important, however, because how the current closes and how these loops change in space and time governs the magnetic topology of the magnetosphere and therefore controls the physical processes of geospace. Furthermore, many methods exist for identifying the regions of near-Earth space carrying each type of current. This study presents a robust collection of these definitions of current systems in geospace, particularly in the near-Earth nightside magnetosphere, as viewed from a variety of observational and computational analysis techniques. The influence of definitional choice on the resulting interpretation of physical processes governing geospace dynamics is presented and discussed.

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Source: https://tomesphere.com/paper/1701.04714