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Main Authors: Sadeghi, R., Tavabi, E.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.07168
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author Sadeghi, R.
Tavabi, E.
author_facet Sadeghi, R.
Tavabi, E.
contents Solar winds originate from the Sun and can be classified as fast or slow. Fast solar winds come from coronal holes at the solar poles, while slow solar winds may originate from the equatorial region or streamers. Spicules are jet-like structures observed in the Sun's chromosphere and transition region. Some spicules exhibit rotating motion, potentially indicating vorticity and Alfven waves. Machine learning and the Hough algorithm were used to analyze over 3000 frames of the Sun, identifying spicules and their characteristics. The study found that rotating spicules, accounting for 21 percent at the poles and 4 percent at the equator, play a role in energy transfer to the upper solar atmosphere. The observations suggest connections between spicules, mini-loops, magnetic reconnection, and the acceleration of fast solar winds. Understanding these small-scale structures is crucial for comprehending the origin and heating of the fast solar wind.
format Preprint
id arxiv_https___arxiv_org_abs_2408_07168
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Characterizing Solar Spicules and their Role in Solar Wind Production using Machine Learning and the Hough Transform
Sadeghi, R.
Tavabi, E.
Solar and Stellar Astrophysics
Space Physics
Solar winds originate from the Sun and can be classified as fast or slow. Fast solar winds come from coronal holes at the solar poles, while slow solar winds may originate from the equatorial region or streamers. Spicules are jet-like structures observed in the Sun's chromosphere and transition region. Some spicules exhibit rotating motion, potentially indicating vorticity and Alfven waves. Machine learning and the Hough algorithm were used to analyze over 3000 frames of the Sun, identifying spicules and their characteristics. The study found that rotating spicules, accounting for 21 percent at the poles and 4 percent at the equator, play a role in energy transfer to the upper solar atmosphere. The observations suggest connections between spicules, mini-loops, magnetic reconnection, and the acceleration of fast solar winds. Understanding these small-scale structures is crucial for comprehending the origin and heating of the fast solar wind.
title Characterizing Solar Spicules and their Role in Solar Wind Production using Machine Learning and the Hough Transform
topic Solar and Stellar Astrophysics
Space Physics
url https://arxiv.org/abs/2408.07168