Gamma Rays from Solar Flares

N. Mandzhavidze, R. Ramaty
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引用次数: 19

Abstract

We review recent results obtained from the analysis of the solar flare gamma ray line emission: (a) The gamma ray derived ambient elemental abundances show that the First Ionization Potential (FIP) effect already sets in at relatively low altitudes in the solar atmosphere. (b) The composition of the flare accelerated particles that produce the gamma rays exhibit heavy element and 3He abundance enhancements that are typical for impulsive flares. Unlike the solar energetic particle (SEP) observations in interplanetary space, the gamma ray method allows us to trace the time development of these enhancements. (c) Solar flare gamma ray spectroscopy provides the most direct measure of the abundances of the two very high FIP elements, He and Ne, in subcoronal regions leading to somewhat higher abundances than the generally accepted values. (d) The high intensities of the act lines observed from a number of flares imply a high (≳ 0.1) ambient He/H and/or accelerated α/p. (e) There are indications for the isotopic fractionation of He from the photosphere to corona that has important implications on the mechanism of solar wind acceleration, the protosolar deuterium abundance and Galactic chemical evolution.
来自太阳耀斑的伽马射线
我们回顾了最近从太阳耀斑伽马射线线发射分析中获得的结果:(a)伽马射线衍生的环境元素丰度表明,第一电离势(FIP)效应已经在太阳大气中相对较低的高度出现。(b)产生伽马射线的耀斑加速粒子的组成表现出冲动性耀斑典型的重元素和3He丰度增强。与行星际空间的太阳高能粒子(SEP)观测不同,伽马射线方法使我们能够追踪这些增强的时间发展。(c)太阳耀斑伽马射线光谱学提供了两种非常高的FIP元素He和Ne在日冕下区域丰度的最直接测量,导致丰度略高于普遍接受的值。(d)从许多耀斑观测到的高强度的行为线意味着高(≥0.1)的环境He/H和/或加速α/p。(e)氦从光球到日冕的同位素分馏迹象对太阳风加速机制、原太阳氘丰度和银河系化学演化具有重要意义。
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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