Tracking Non-Radial Outflows in Extreme Ultraviolet and White Light Solar Images

TL;DR

This paper develops a method to analyze non-radial outflows in the solar corona using advanced image processing, tomographic reconstruction, and spectral analysis, providing new insights into solar wind dynamics during solar minimum.

Contribution

It introduces a novel approach combining image processing and tomography to generate non-radial height-time profiles of coronal outflows from remote sensing data.

Findings

Identified oscillatory behavior of streamer boundaries at specific heights.

Generated non-radial profiles of plasma outflows from the Sun.

Tracked outflows from EUV to white light observations.

Abstract

Understanding the solar corona requires knowledge of its dynamics through its various layers and subsequent connectivity to the heliosphere. This requires understanding the nature of the outflows and the physical transitions through the middle corona (~1.5-6.0 Rs). While this region is still inaccessible to in situ measurements, remote sensing observations are available, but their interpretation can be controversial due to line-of-sight effects and the non-radial motion of outflowing structures close to the Sun (<3.0 Rs). In this work, we describe a method to mitigate these challenges by generating non-radial Height-Time profiles of outflows by using advanced image processing techniques. The North and South boundaries of a large equatorial streamer during the 2008 solar minimum were identified in STEREO/SECCHI solar images, using two different methodologies based on thresholds of brightness and piece-wise polynomial function fitting. To address line-of-sight issues, we used tomographic reconstruction of the 3D distribution of the coronal electron density based on SECCHI/COR2 images. Spectral analysis of the time series of the position angle of the streamer boundary revealed its oscillatory nature at some heights at 36-48 hours and 10.5-14.6 hours. Dividing the distance between the North and South streamer boundaries in equal parts at each height, we obtained non-radial Height-Time paths from which we generated non-radial profiles of corona/solar wind plasma outflow. We tracked outflows as they moved uninterruptedly from the Sun in EUVI, through COR1 and into COR2. Finally, we discuss preliminary results of non-radial plane-of-sky velocities for a CME and two small-scale features.