Coronal Mass Ejections: Observations

IF 20.9 1区 物理与天体物理
David F. Webb, Timothy A. Howard
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引用次数: 485

Abstract

Solar eruptive phenomena embrace a variety of eruptions, including flares, solar energetic particles, and radio bursts. Since the vast majority of these are associated with the eruption, development, and evolution of coronal mass ejections (CMEs), we focus on CME observations in this review. CMEs are a key aspect of coronal and interplanetary dynamics. They inject large quantities of mass and magnetic flux into the heliosphere, causing major transient disturbances. CMEs can drive interplanetary shocks, a key source of solar energetic particles and are known to be the major contributor to severe space weather at the Earth. Studies over the past decade using the data sets from (among others) the SOHO, TRACE, Wind, ACE, STEREO, and SDO spacecraft, along with ground-based instruments, have improved our knowledge of the origins and development of CMEs at the Sun and how they contribute to space weather at Earth. SOHO, launched in 1995, has provided us with almost continuous coverage of the solar corona over more than a complete solar cycle, and the heliospheric imagers SMEI (2003–2011) and the HIs (operating since early 2007) have provided us with the capability to image and track CMEs continually across the inner heliosphere. We review some key coronal properties of CMEs, their source regions and their propagation through the solar wind. The LASCO coronagraphs routinely observe CMEs launched along the Sun-Earth line as halo-like brightenings. STEREO also permits observing Earth-directed CMEs from three different viewpoints of increasing azimuthal separation, thereby enabling the estimation of their three-dimensional properties. These are important not only for space weather prediction purposes, but also for understanding the development and internal structure of CMEs since we view their source regions on the solar disk and can measure their in-situ characteristics along their axes. Included in our discussion of the recent developments in CME-related phenomena are the latest developments from the STEREO and LASCO coronagraphs and the SMEI and HI heliospheric imagers.

Abstract Image

日冕物质抛射:观测
太阳爆发现象包括各种各样的爆发,包括耀斑、太阳高能粒子和射电爆发。由于其中绝大多数都与日冕物质抛射(CME)的喷发、发展和演化有关,因此本文将重点介绍CME的观测结果。日冕物质抛射是日冕和行星际动力学的一个关键方面。它们向日球层注入大量质量和磁通量,造成重大的瞬态扰动。日冕物质抛射可以驱动行星际冲击,这是太阳高能粒子的主要来源,也是造成地球恶劣太空天气的主要原因。在过去的十年中,利用SOHO、TRACE、Wind、ACE、STEREO和SDO航天器以及地面仪器的数据集进行的研究,提高了我们对太阳日冕物质抛射的起源和发展以及它们如何影响地球空间天气的认识。SOHO于1995年发射,为我们提供了超过一个完整太阳周期的日冕几乎连续的覆盖,日球层成像仪SMEI(2003-2011)和he(自2007年初开始运行)为我们提供了在内日球层连续成像和跟踪cme的能力。我们回顾了日冕物质抛射的一些关键的日冕性质,它们的来源区域和它们在太阳风中的传播。LASCO日冕仪定期观测沿日地线发射的日冕物质抛射,形成类似光晕的光亮。STEREO还允许从三个不同的角度观察地球方向的日冕物质抛射,从而增加方位角分离,从而能够估计它们的三维特性。这不仅对空间天气预报很重要,而且对了解日冕物质抛射的发展和内部结构也很重要,因为我们可以在太阳盘中看到它们的来源区域,并可以沿着它们的轴线测量它们的原位特征。在我们对日冕物质抛射相关现象的最新进展的讨论中,包括来自STEREO和LASCO日冕仪以及SMEI和HI日球成像仪的最新进展。
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来源期刊
Living Reviews in Solar Physics
Living Reviews in Solar Physics ASTRONOMY & ASTROPHYSICS-
自引率
1.40%
发文量
3
期刊介绍: Living Reviews in Solar Physics, a platinum open-access journal, publishes invited reviews covering research across all areas of solar and heliospheric physics. It distinguishes itself by maintaining a collection of high-quality reviews regularly updated by the authors. Established in 2004, it was founded by the Max Planck Institute for Solar System Research (MPS). "Living Reviews®" is a registered trademark of Springer International Publishing AG.
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