Impulsive, ~3He-rich events originate close to the interface between slow solar wind overlying active regions and a faster solar wind coming from small coronal holes. This causes large-scale magnetic compressions to be an interplanetary environment for solar energetic particle (SEP) transport in impulsive events, which is typically ignored by SEP modelers. We have modeled SEP transport in a simplified corotating solar wind structure to estimate the possible effect of the rising wind speed on particle anisotropy and spectra at 1 AU. Along with traditional modeling of SEP transport in the static magnetic field and the field-aligned solar wind flow of the corotating frame of reference, we have formulated and tested a new model that is the first model of focused transport applicable to a general case of SEP propagation in realistic, dynamic, and structured solar wind. Numerical modeling shows that a fast increase of the wind speed by only 200 km s~(-1) can strongly affect the SEP flux anisotropy at 1 AU. Accurate analysis of impulsive SEP events can be done with the use of solar wind data, SEP flux anisotropy measurements, and the new approach that accounts for the solar wind structures associated with the sources of impulsive events and uses the general solution of the focused transport problem applicable to SEPs in realistic solar wind.
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机译:冲动的〜3He富集事件起源于覆盖活跃区域的缓慢太阳风与来自小日冕孔的较快太阳风之间的界面。这导致大规模的磁压缩成为脉冲事件中太阳高能粒子(SEP)传输的行星际环境,这通常被SEP建模人员忽略。我们在简化的同向旋转太阳风结构中对SEP输运进行了建模,以估算风速升高对1 AU下粒子各向异性和光谱的可能影响。结合传统的SEP在静磁场中的传输模型和同向旋转参考系的场对准太阳风流,我们制定并测试了一个新模型,这是适用于SEP一般情况的第一个聚焦传输模型在现实,动态和结构化的太阳风中传播。数值模拟表明,风速仅增加200 km s〜(-1)即可强烈影响1 AU时的SEP通量各向异性。可以使用太阳风数据,SEP通量各向异性测量以及考虑与脉冲事件源相关的太阳风结构并使用集中运输问题的一般解决方案的新方法来完成对脉冲SEP事件的准确分析。适用于现实太阳风中的SEP。
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