对日冕物质抛射分类的定量研究

众所周知，日冕物质抛射（CME）的性质强烈地决定于其结构，故对日冕物质抛射的结构进行强度分类，对研究日地事件有重要的意义，利用模糊综合评判方法，可对日冕物质抛射的分类进行定量研究，该方法通常需考虑多个因素，如各类CME的速度、跨度、质量和动能。将其作为评判因素集，并确定相应的隶属度函数，通过计算，可以将CME分成强（strong）、中（middle）、弱（weak）3大类，并根据隶属度值的大小，给出各类CME平均特性的相对强弱排序，分析表明模糊综合评判方法优于一般的统计方法。     

基于Faster R-CNN的日冕物质抛射检测方法

日冕物质抛射(Coronal Mass Ejection,CME)是一种强烈的太阳爆发现象,对空间天气和人类生活有巨大的影响,因此,日冕物质抛射检测对预报日冕物质抛射、保障人类的生产生活安全具有重要意义。现有的日冕物质抛射检测多采用人为定义特征和界定阈值等方法。由于人为定义特征不能准确表征日冕物质抛射且具有普适性的阈值难于选择,现有的方法对日冕物质抛射的检测效果有待提高。提出一种基于Faster R-CNN(Faster Region-based Convolutional Neural Networks)的日冕物质抛射检测算法。该方法首先结合CDAW(Coordinated Data Analysis Workshop Data Center),SEEDS(Solar Eruptive Even Detection System)和CACTus(Computer Aoded CME Tracking software package)3个著名的日冕物质抛射目录信息,人工标注了包含9113幅日冕图像的数据集,然后根据日冕物质抛射的图像特征较自然图像少、目标尺寸与自然图像有差异等特点,在特征提取和锚点选择方面对Faster R-CNN进行改进。以2007年6月的日冕物质抛射标注数据为测试集,本文算法检出了全部22个强日冕物质抛射事件和151个弱日冕物质抛射事件中的138个,对日冕物质抛射事件的中心角和角宽度等特征参数的检测误差分别在5°和10°以内。     

日冕物质抛射的偏转特性研究

日冕物质抛射(CME)是巨大的、携带磁力线的泡沫状气体,在几个小时中被从太阳抛射出来的过程。日冕物质抛射伴随着大量带电粒子和辐射的释放,这些物质进入日地空间,对日地空间的磁场造成很大扰动;当它们传播到地球附近时,则严重影响地球的磁场,产生磁暴,也对空间和地面的电子设备造成干扰。日冕物质抛射在传播过程中如果发生偏转,将影响它对地有效性。因此研究日冕物质抛射的偏转特性,对预报日冕物质抛射对日地空间的影响具有重要意义。主要利用2007年10月8日STEREO卫星的日冕物质抛射观测资料,结合全日面线性无力场模型(Global Linear Force-Free Field,GLFFF)进行磁场外推,分析日冕物质抛射偏转与背景磁场能量密度分布之间的关系,并计算日冕物质抛射的运动轨迹。通过改变无力因子α,发现当α=0.15时,计算得到的日冕物质抛射运动轨迹与实际观测的日冕物质抛射运动轨迹拟合得最好。     

日冕物质抛射

评述了近几年来冕物抛射研究的新进展,包括Ｙｏｈｋｏｈ、ＳＯＨＯ、ＷＩＮＤ、Ｕｌｙｓｓｅｓ、Ｇｅｏｔａｉｌ和ＰＯＬＡＲ等飞船最近取得的观测结果,并由典型事件探计日冕物质抛射与太阳活动、行星际扰动和地球空间环境变化之间的关系。进而介绍日冕物质抛射形成机制和传播过程的主要理论模型和数值模拟结果,提出今后日冕物质抛射研究中一些值得注意的问题。     

日冕物质抛射检测研究进展

日冕物质抛射是一种规模巨大、程度剧烈的爆发现象,是影响地球的主要太阳爆发活动。由于这种爆发现象对地球环境造成严重干扰,因此,日冕物质抛射的探测对预报灾害性空间天气具有重要意义。为了更清楚地梳理目前存在的日冕物质抛射检测方法,对典型的方法进行分析总结。首先,介绍日冕物质抛射及其特征;然后,从基于手工方法和自动检测方法两方面对日冕物质抛射检测进行概述和分析;最后,讨论目前算法存在的一些问题,进而提出未来的研究方向。     

爆发日珥与日冕物质抛射的观测研究

本文比较了1982年2月9日同时观测到的两个爆发日珥及一次白光日冕物质抛射事件。比较表明,在研究日冕物质抛射事件与爆发日珥的关系时,爆发日珥的形状可能是一个重要的因素,它体现了局部区域磁场结构的变化。作者提出了一种可能的磁场结构模型,对观测结果给以解释。     

一个引人注目的CME事件与共生现象的分析研究

根据1991年6月15日发生的微波、分米波、米波、十米波等波段内射电爆发以及质子事件，地磁暴等进行了分析研究，认为产生各种物理过程的有效机制和动因是日冕物质抛射而非太阳耀斑。     

日冕物质抛射的中性电流片及边源辐射对

利用日本阳光卫星上的软X－射线望远镜，硬X－射线望远镜和野边山射电日像仪1998年4月23日观测资料，对软X－射线日冕物质抛射和射电Ⅳ型爆发进行了综合研究，获得了下列有意义的结果。在2个磁偶极源之间发现了磁容带和少数的激活源。激活源将磁容带变成磁能带的过程，正是中性电流片的形成过程以及激发能量和发亮物质向它集中的过程。当2个磁偶极源被磁能带接通时，则中性电流片形成，并且发生软X－射线日冕物质抛射。物质抛射不仅从中性电流片处升起，也从整个磁能带上升起。软X－射线日冕物质抛射环具有2个足点，它们正是2个磁偶极源。膨胀环的头总是倾向于弱源的足点，因为它是来自2个足点磁压的平衡点。因此它的轨迹是中性线，由中性线便可确定中性电流片的位置。最后，发现了磁能带上中性电流片的边缘辐射对。     

冕流与日冕物质抛射的关系

本文研究了卡林顿自转周１５９１ － １５９２ 中冕流偏振亮度的变化。冕流带偏振亮度的分布是不均匀的,不均匀度为１０ ％ － ５０ ％ 。无日冕物质抛射影响存在时,沿冕流带冕流的分布可持续稳定存在近两个太阳自转周。当一个日冕物质抛射伴随冕流产生时,冕流的经向角大小若大于２７°,可导致冕流尖角区顶部上升速度大于２ｋｍ／ｓ。     

一个引人注目的CME事件与共生现象的分析研究

根据1991年6月15日发生的微波、分米波、米波、十米波等波段内射电爆发以及质子事件、地磁暴等进行了分析研究,认为产生各种物理过程的有效机制和动因是日冕物质抛射而非太阳耀斑。     

Different Types of Coronal Mass Ejections At Minimum and Maximum of Solar Activity and Their Relation to Magnetic Field Evolution

Coronal mass ejections (CMEs) are considered to be associated with large-scale, closed magnetic field structures in the corona. These structures change throughout the solar activity cycle following the evolution of the general solar magnetic field. To study the variation of CME characteristics with the evolution of coronal magnetic structures, we compute the 3-D coronal magnetic field at minimum and maximum of activity with a source-surface potential field model. In particular, we study the central latitude distribution of CMEs and the frequency of occurrence of the different CME types in these two periods. We find that most CMEs are indeed associated with large-scale, magnetically closed structures, and their latitudinal distribution follows the solar cycle latitudinal changes of the location of these structures. We also find that different CME types, which constitute different fractions of the total during the maximum and the minimum, are associated with different shapes and orientations of the closed structures at different times of the solar cycle.     

A Statistical Study on the Geomagnetically Induced Current Events Driven by Earth-directed Full-Halo Coronal Mass Ejections

Solar activities can cause the anomalies of electric power transmission systems, especially, for an extra-long distance transmission system. Using the data of coronal mass ejection (CME) from SOHO/LASCO (Solar and Heliospheric Observatory/Large Angle and Spectrometric Coronagraph), and the data of the geomagnetically induced current (GIC) and geomagnetic storm from the North China Electric Power University and Finnish Meteorological Institute, respectively, we analyze some important observational features and physical properties of the earth-directed halo CMEs associated with the GIC events. After classifying the observed halo CMEs according to their symmetry, it is found that the halo CMEs associated with GIC events are mainly the 3 types: completely symmetric, brightness-asymmetric, and outline-asymmetric. The geomagnetically induced current events driven by the three different types of halo CMEs have different characteristics in the intensity, duration, and period. We ?nd that the brightness-asymmetric halo CMEs are most likely to cause the major damage to the transmission systems. And that the geomagnetically induced current has also a good correlation with the time variation of geomagnetic ?eld.     

日冕物质抛射的观测性质

综述日冕物质抛射的观测和持性，简短的前言之后，给出ＣＭＥ的发现经过及统计特性，着重介绍ＣＭＥ与其他种类太阳活动的相关。然后介绍ＣＭＥ的一般特性，包括可能与ＣＭＥ相关的一些物理过程的观测特性。初步结论是：ＣＭＥ是一种演变中的磁结构现象。     

Activity associated with the solar origin of coronal mass ejections

Solar coronal mass ejections (CMEs) observed in 1980 with the HAO Coronagraph/Polarimeter on the Solar Maximum Mission (SMM) satellite are compared with other forms of solar activity that might be physically related to the ejections. The solar phenomena checked and the method of association used were intentionally patterned after those of Munro et al.'s (1979) analysis of mass ejections observed with the Skylab coronagraph to facilitate comparison of the two epochs. Comparison of the results reveals that the types and degree of CME associations are similar near solar activity minimum and at maximum. For both epochs, most CMEs with associations had associated eruptive prominences and the proportions of association of all types of activity were similar. We also found a high percentage of association between SMM CMEs and X-ray long duration events (LDEs), in agreement with Skylab results. We conclude that most CMEs are the result of the destabilization and eruption of a prominence and its overlying coronal structure, or of a magnetic structure capable of supporting a prominence.Much of this work was performed as a Visiting Scientist at the High Altitude Observatory/NCAR.The National Center for Atmospheric Research is sponsored by the National Science Foundation.     

Cme Phenomenology in Different Solar Magnetic Scenarios

The existence of three magnetic scenarios with magnetic field intensities one order apart was considered. CMEs were associated to different solar activity phenomena and solar features showing different characteristics. Those associated to intense magnetic fields were more complex, having either more components or multiple emissions and a greater magnetic energy to particle acceleration conversion rate. On the other hand, simple CMEs were found to associate to weak magnetic fields. No evidence was found that the process that leads to CME starts before their detection at 1.6 solar radii. This indicates that the whole volume moves upward simultaneously, no matter how deep it reaches into the solar atmosphere.     

日冕物质抛射的低频射电特征

日冕物质抛射(ChIEs)经常被观测到和其他日面活动相伴生，太阳耀斑、日珥爆发、盔状冕流等许多太阳现象，都与它有直接或间接的关系。射电观测是研究CMEs的一种重要的补充工具。多频率的射电成像观测能很好地研究CMEs的初始阶段，而且可以得到关于CMEs触发机制特征的更多信息。概括了CMEs与低频射电的关系，介绍了低频射电的观测仪器，分析了CMEs低频射电所表现出来的特征，考虑了CMEs的初发机制，总结了尚待解决的问题，表明了CMEs研究是基于多类数据和全电磁辐射波段的。     

Three-Dimensional Reconstruction of Two Solar Coronal Mass Ejections Using the STEREO Spacecraft

Previous attempts to produce three-dimensional (3-D) reconstructions of coronal mass ejections (CMEs) have required either modeling efforts or comparisons with secondary associated eruptions near the solar surface. This is because coronagraphs are only able to produce sky-plane-projected images of CMEs and it has hence been impossible to overcome projection effects by using coronagraphs alone. The SECCHI suite aboard the twin STEREO spacecraft allows us to provide the means for 3-D reconstruction of CMEs directly from coronagraph measurements alone for the first time. We present these measurements from two CMEs observed in November 2007. By identifying common features observed simultaneously with the LASCO coronagraphs aboard SOHO and the COR coronagraphs aboard STEREO we have triangulated the source region of both CMEs. We present the geometrical analysis required for this triangulation and identify the location of the CME in solar-meridional, ecliptic, and Carrington coordinates. None of the two events were associated with an easily detectable solar surface eruption, so this triangulation technique is the only means by which the source location of these CMEs could be identified. We present evidence that both CMEs originated from the same magnetic structure on the Sun, but from a different magnetic field configuration. Our results reveal some insight into the evolution of the high corona magnetic field, including its behavior over time scales of a few days and its reconfiguration after a major eruption.     

A Study of Surges: II. On the Relationship between Chromospheric Surges and Coronal Mass Ejections

Liu et al. (Astrophys. J. 628, 1056, 2005a) described one surge – coronal mass ejection (CME) event showing a close relationship between solar chromospheric surge ejection and CME that had not been noted before. In this work, large Hα surges (>72 Mm, or 100 arcsec) are studied. Eight of these were associated with CMEs. According to their distinct morphological features, Hα surges can be classified into three types: jetlike, diffuse, and closed loop. It was found that all of the jetlike surges were associated with jetlike CMEs (with angular widths ≤30 degrees); the diffuse surges were all associated with wide-angle CMEs (e.g., halo); the closed-loop surges were not associated with CMEs. The exclusive relation between Hα surges and CMEs indicates difference in magnetic field configurations. The jetlike surges and related narrow CMEs propagate along coronal fields that are originally open. The unusual transverse mass motions in the diffuse surges are suggested to be due to magnetic reconnections in the corona that produce wide-angle CMEs. For the closed-loop surges, their paths are just outlining stable closed loops close to the solar surface. Thus no CMEs are associated with them.     

A Numerical Study of the Response of the Coronal Magnetic Field to Flux Emergence

Large-scale solar eruptions, known as coronal mass ejections (CMEs), are regarded as the main drivers of space weather. The exact trigger mechanism of these violent events is still not completely clear; however, the solar magnetic field indisputably plays a crucial role in the onset of CMEs. The strength and morphology of the solar magnetic field are expected to have a decisive effect on CME properties, such as size and speed. This study aims to investigate the evolution of a magnetic configuration when driven by the emergence of new magnetic flux in order to get a better insight into the onset of CMEs and their magnetic structure. The three-dimensional, time-dependent equations for ideal magnetohydrodynamics are numerically solved on a spherical mesh. New flux emergence in a bipolar active region causes destabilisation of the initial stationary structure, finally resulting in an eruption. The initial magnetic topology is suitable for the ??breakout?? CME scenario to work. Although no magnetic flux rope structure is present in the initial condition, highly twisted magnetic field lines are formed during the evolution of the system as a result of internal reconnection due to the interaction of the active region magnetic field with the ambient field. The magnetic energy built up in the system and the final speed of the CME depend on the strength of the overlying magnetic field, the flux emergence rate, and the total amount of emerged flux. The interaction with the global coronal field makes the eruption a large-scale event, involving distant parts of the solar surface.     

投影改正后CME的速度分布

目前观测的CME(日冕物质抛射)是其在天空平面的投影,这就导致CME的观测参量与真实参量之间存在一定的差异,比如说观测到的CME速度一般要比CME的真实速度小.运用基于锥状模型对CME的速度进行投影改正的方法,分析1996年9月到2007年9月(将近1个活动周)SOHO/LASCO日冕仪观测到的1 691个仅与耀斑相关的CME(简称FL类CME)和610个仅与暗条爆发相关的CME(简称FE类CME)投影改正前后的速度分布,得到如下结果:(1)投影改正前后,FL类CME和FE类CME的速度分布非常相似.且投影改正前后,两类CME的平均速度几乎相同; (2)投影改正前后,FL类CME和FE类CME速度的自然对数分布也非常相似.