February 25, 2014 solar flare data analysis in SunPy

Physical Sciences and Technology Pub Date : 2020-12-29 DOI:10.26577/phst.2020.v7.i2.03

A. Sarsembayeva, F. Belisarova, M. Odsuren, A. Sarsembay

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引用次数: 2

Abstract

Solar flares are strong radiation bursts, whereas large clouds of solar material and magnetic fields thaterupt at high speeds from the Sun are coronal mass ejections. Harmful radiation from a flare does notpass through the atmosphere of the Earth to physically impact humans on the ground, but can disrupt theatmosphere in the layer where GPS and communication signals travel. Flares generate results across theentire electromagnetic spectrum. They emit x-rays and ultraviolet radiation, which means extremely hightemperatures during a flash. Radio waves mean that tiny fractions of particles are accelerated to high levelsof energy. Most of the radiation is synchrotron radiation produced along magnetic field lines by electronstraveling along spiral paths. In this paper was monitored solar flare registered on February 25, 2015. Thisflare, which peaked at 00:49 am EDT from a sunspot called Active Region 1990 (AR1990), is classifiedas an X4.9-class flare. We have performed solar data analysis using the Python/SunPy tool. SunPy waschosen as the principle data analysis environment since it provides easy to use interfaces to the Virtual SolarObservatory (VSO).

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2014年2月25日太阳耀斑数据分析

太阳耀斑是强烈的辐射爆发，而太阳物质和磁场的大云以高速从太阳喷发是日冕物质抛射。耀斑产生的有害辐射不会穿过地球大气层对地面上的人类产生物理影响，但会破坏GPS和通信信号传播的大气层。耀斑产生的结果横跨整个电磁波谱。它们发出x射线和紫外线辐射，这意味着在闪光期间温度极高。无线电波意味着微小的粒子被加速到高能级。大部分辐射是电子沿螺旋路径沿磁力线产生的同步辐射。本文监测的是2015年2月25日注册的太阳耀斑。这次耀斑在美国东部时间上午0点49分达到峰值，来自一个被称为1990活跃区(AR1990)的太阳黑子，被归类为x4.9级耀斑。我们使用Python/SunPy工具进行了太阳数据分析。之所以选择SunPy作为主要的数据分析环境，是因为它为虚拟太阳天文台(VSO)提供了易于使用的接口。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Physical Sciences and Technology

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