利用机器学习和霍夫变换表征太阳尖晶石及其在太阳风生产中的作用

arXiv - PHYS - Space Physics Pub Date : 2024-08-13 DOI:arxiv-2408.07168

R. Sadeghi, E. Tavabi

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引用次数: 0

摘要

快速太阳风来自太阳两极的日冕洞，而慢速太阳风可能来自赤道区或流线体。一些星芒表现出旋转运动，可能表示涡度和阿尔芬波。研究发现，旋转的星芒在两极占21%，在赤道占4%，在向上层太阳大气传递能量方面发挥着作用。这些观测结果表明，棘球、小型环、磁重连和快速太阳风的加速之间存在联系。了解这些小尺度结构对于理解快速太阳风的起源和加热至关重要。

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Characterizing Solar Spicules and their Role in Solar Wind Production using Machine Learning and the Hough Transform

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.

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arXiv - PHYS - Space Physics

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