# Mapping Magnetic Field Lines for an Accelerating Solar Wind

**Authors:** S. Tasnim, Iver H. Cairns, B. Li, and M. S. Wheatland

arXiv: 1907.08683 · 2020-01-08

## TL;DR

This paper enhances magnetic field line mapping for the solar wind by incorporating acceleration, intrinsic magnetic fields, and angular momentum conservation, resulting in more accurate local structures and better agreement with observations.

## Contribution

The study generalizes existing magnetic field line mapping methods to include solar wind acceleration and intrinsic magnetic effects, improving local structure predictions.

## Key findings

- Maps are similar on large scales between models.
- Small-scale structural differences are notable.
- Predicted electron pitch angle distributions match observations 90-95%.

## Abstract

Mapping of magnetic field lines is important for studies of the solar wind and the sources and propagation of energetic particles between the Sun and observers. A recently developed mapping approach is generalised to use a more advanced solar wind model that includes the effects of solar wind acceleration, non-radial intrinsic magnetic fields and flows at the source surface/inner boundary, and conservation of angular momentum. The field lines are mapped by stepping along local magnetic field $\bm{B}$ and via a Runge-Kutta algorithm, leading to essentially identical maps. The new model's maps for Carrington rotation CR 1895 near solar minimum (19 April to 15 May 1995) and a solar rotation between CR 2145 and CR 2146 near solar maximum (14 January to 9 February 2014) are compared with the published maps for a constant solar wind model. The two maps are very similar on a large scale near both solar minimum and solar maximum, meaning that the field line orientations, winding angles, and connectivity generally agree very well. However, close inspection shows that the field lines have notable small-scale structural differences. An interpretation is that inclusion of the acceleration and intrinsic azimuthal velocity has significant effects on the local structure of the magnetic field lines. Interestingly, the field lines are more azimuthal for the accelerating solar wind model for both intervals. In addition, predictions for the pitch angle distributions (PADs) for suprathermal electrons agree at the $90$ -- $95\%$ level with observations for both solar wind models for both intervals.

## Full text

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## Figures

27 figures with captions in the complete paper: https://tomesphere.com/paper/1907.08683/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1907.08683/full.md

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Source: https://tomesphere.com/paper/1907.08683