太阳活动区冕环若干研究进展

日冕加热是太阳物理中一个基本问题。随着一批高性能仪器（如TRACE、SOHO、Yohkoh）投入观测，作为太阳日冕中一种基本结构的冕环，其观测资料日益丰富。冕环加热是日冕加热的一个重要组成部分，越来越得到人们的重视。在简要介绍冕环最新观测和研究进展后，以其一维模型为基础，着重讨论了现有冕环加热结构和加热机制的研究进展。     

太阳活动低年的外冕结构

对１９９７年３月９日漠河日全食时的外冕进行了摄像观测,采用天文视频图像采集处理系统对该资料进行了处理,并对太阳活动低年的外冕形态和结构特征进行了初步分析。     

吸积盘和冕的研究与应用

本文主要研究有热冕存在的吸积盘的特征。首先，我们采用最新的不透明度表和态方程表对经典薄盘的结构进行了探讨。然后考虑吸积盘上下方存在的热冕，分析了冕中的物理过程并研究了冕的结构。在此基础上，我们计算了有冕盘的结构并与无冕盘比较，讨论了盘冕共存系统中物质的蒸发。采用内区径流（亦译为平流）ADAF主导吸积与外区有冕盘吸积方案，研究了黑洞双星系统中光谱态之间转换的作用，提出了黑洞双星系统中光谱态转换的新机制，主要研究成果如下：1、不透明度是吸积盘不稳定性的重要因素。不透明度表和相应的态方程表的改进对吸积盘结构的影响不大，相对于粘滞系数和混合程的不确定性而言是可以忽略的。2、系统的冕结构研究表明，冕的存在对盘的结构有重要影响。吸积物质从冷盘蒸发到热冕中会使内盘物质耗空，在内区只有冕存在。这样的结构将对吸积盘的辐射产生重要作用。3、数值计算了冕的演化，发现物质蒸发使吸积盘理论能自然地诠释如下观测特征：矮新星爆发中出现的紫外边延滞、X－射线后爆发，以及爆发温度。然后，我们提出了新的关于WZ Sge型矮新星和X－射线新星在沉寂阶段的演化模型。在此基础上，我们数值模拟了WZ Sge的长周期演化。4、提出了冕盘的蒸发是吸积从外区薄盘向内区ADAF转化的原因。利用蒸发模型计算了X－射线瞬变源的转换半径，发现理论值与观测值基本一致。5、用有冕盘蒸发模型探讨了X－射线双星中（如Cyg X-1,LMC X-1,LMC X-3)光谱态、从硬到软的变化，发现吸积率的变化导致了ADAF和薄盘之间转换半径的变化，从而使光谱态发生了变化。     

1986年2月4日耀斑与电流环合并不稳定性

本文收集了１９８６年２月４日大耀斑的Ｈα、微波、Ｘ射线和γ射线全波段的观测资料。利用暗条电流环模型分析了该耀斑的物理过程，测量了活动暗条的上升运动，求解了动量方程和能量方程。结果表明：（１）１９８６年２月４日的３Ｂ／Ｘ３耀斑可能是由暗条电流环之间的合并不稳定性所致；（２）电阻撕裂摸不稳定性是一种有效的耀斑前预热机制；（３）耀斑的高能观测资料进一步表明了电流环合并不稳定性是引起该大耀斑期间所有高能粒     

活动双星的X射线冕活动

本文介绍了ＲＯＳＡＴ卫星对活动双星的观测及其观测性质,并比较活动双星的冕活动与同光谱带单层的不同,探讨次星的存在和质量转移对双量活动性的影响。     

罕见而神秘的变星——北冕座R型变星

在所有曲变星类型中,北冕座R型变星无疑是最引人注目的。由于亮度原因,这类变星发现的数量非常稀少,甚至比超新星还要少得多。但它们有着各种不同寻常的行为,包括光变曲线、光谱、消光曲线、红外辐射等等。自1795年第一颗北冕座R型变星发现以来,人们对它们的研究始终没有停止过,但至今仍有很多谜团有待我们解决。     

太阳多极活动区中的磁重磁,剪切低磁弧内的强电流和冕穴结构

探讨了复杂磁结构上空日冕物现状与磁剪切的关系。结果表明在强磁场的磁中性线上方磁剪切会引起具有强电流和较强等离子体压力的低磁弧。这可解释Ｙｏｈｋｏｈ卫星的观测结果。     

冕环振荡的物理特征研究

太阳动力学观测站(Solar Dynamics Observatory,SDO)上的太阳大气成像仪(Atmospheric Imaging Assembly,AIA)利用谱线Fe IX 171 (A)在2010年10月16日对整个日面进行了连续的高分辨率观测,获得了高质量的数据.这些高质量的数据提供了仔细研究冕环振荡的样本.通过分析这份数据,发现活动区NOAA 1112在此期间爆发了一个M2.9级的耀斑.该耀斑触发了太阳表面的多个冕环产生强烈振荡.其中最为明显的两个振荡冕环呈现出截然不同的振荡特征.位于西492 Mm,南170 Mm(简称W492/S170,后面出现的坐标位置均采取这种标注)处的冕环做周期为pA0 =385 s的简谐振荡,其振荡方程为x=2.2sin[2π55(t-768)],其中t为时间,单位为s;而位于W559/S142处的冕环则是一种典型的阻尼振荡,其阻尼振荡周期为Pf =449 s,相应的振荡方程可表示为x=24.8e-2π/342tsin[2π/449(t-1128)].     

Damped Oscillations of Coronal Loops

A mechanism of damped oscillations of a coronal loop is investigated. The loop is treated as a thin toroidal flux rope with two stationary photospheric footpoints, carrying both toroidal and poloidal currents. The forces and the flux-rope dynamics are described within the framework of ideal magnetohydrodynamics (MHD). The main features of the theory are the following: i) Oscillatory motions are determined by the Lorentz force that acts on curved current-carrying plasma structures and ii) damping is caused by drag that provides the momentum coupling between the flux rope and the ambient coronal plasma. The oscillation is restricted to the vertical plane of the flux rope. The initial equilibrium flux rope is set into oscillation by a pulse of upflow of the ambient plasma. The theory is applied to two events of oscillating loops observed by the Transition Region and Coronal Explorer (TRACE). It is shown that the Lorentz force and drag with a reasonable value of the coupling coefficient (c _d ) and without anomalous dissipation are able to accurately account for the observed damped oscillations. The analysis shows that the variations in the observed intensity can be explained by the minor radial expansion and contraction. For the two events, the values of the drag coefficient consistent with the observed damping times are in the range c _d ≈2 – 5, with specific values being dependent on parameters such as the loop density, ambient magnetic field, and the loop geometry. This range is consistent with a previous MHD simulation study and with values used to reproduce the observed trajectories of coronal mass ejections (CMEs).     

Analysis of Two Coronal Loops with Combined TRACE and SOHO/CDS Data

We use an innovative research technique to analyze combined images from the Coronal Diagnostic Spectrometer (CDS) on the Solar and Heliospheric Observatory (SOHO) and the Transition Region and Coronal Explorer (TRACE). We produce a high spatial and temporal resolution simulated CDS raster or “composite” map from TRACE data and use this composite map to jointly analyze data from both instruments. We show some of the advantages of using the “composite” map method for coronal loop studies. We investigate two postflare loop structures. We find cool material (250 000 K) concentrated at the tips or apex of the loops. This material is found to be above its scale height and therefore not in hydrostatic equilibrium. The exposure times of the composite map and TRACE images are used to give an estimate of another loop’s cooling time. The contribution to the emission in the TRACE images for the spectral lines present in its narrow passband is estimated by using the CDS spectral data and CHIANTI to derive synthetic spectra. We obtain cospatial and cotemporal data collected by both instruments in SOHO Joint Observations Program (JOP) 146 and show how the combination of these data can be utilized to obtain more accurate measurements of coronal plasmas than if analyzed individually. Electronic Supplementary Material  The online version of this article () contains supplementary material, which is available to authorized users.     

由对地全晕状日冕物质抛射诱发的地磁感应电流统计研究

太阳活动会引起输变电系统异常,特别是对超长距离输变电系统的危害尤其明显.根据SOHO/LASCO (Solar and Heliospheric Observatory/Large Angle and Spectrometric Coronagraph)的日冕物质抛射(Coronal Mass Ejection,CME)数据、华北电力大学和芬兰气象研究所获得的地磁感应电流(Geomagnetically Induced Current,GIC)数据以及地磁暴数据,分析研究了与GIC事件有关的对地晕状CME的重要观测特征和物理性质.按照对称性将晕状CME进行分类后,发现造成GIC事件的晕状CME主要有3类:完全对称型、亮度不对称型和外形不对称型.不同类型的全晕状CME驱动的GIC事件在强度、持续时间等方面特征各不相同.其中,亮度不对称型晕状CME很有可能对GIC事件影响最为严重.同时注意到GIC与地磁场随时间的变化率也具有较好的相关性.     

冕洞边缘结构对日冕物质抛射的可能贡献

分析了１９８０ 、１９８４ 和１９８９ 年 Ｓ Ｍ Ｍ 卫星观测到的１４０ 次日冕物质抛射（ Ｃ Ｍ Ｅ） 事件在时空分布上与“冕洞边缘结构”、耀斑爆发和爆发日珥等事件的相关关系。结果表明, Ｃ Ｍ Ｅ 事件与日冕边缘结构的关系最密切。此外, Ｃ Ｍ Ｅ 与赤道冕洞具有同步的长期演化关系。由此认为, 冕洞边缘结构对 Ｃ Ｍ Ｅ 的可能贡献是不可忽视的     

Determination of the True Shape of Coronal Loops

Using line of sight velocity measurements from the SUMER and CDS instruments aboard SOHO, in conjunction with a simple geometrical model, we reconstructed the true, 3D shape and the velocity of plasma flow along coronal loops. The projection of the loop on the sky and the position of the footpoints define a family of curves. Assuming that the loop is located on a plane, the line of sight velocity can be used to select the most plausible solution. For two loops, observed in the Ne viii? 770 Å and O v? 630 Å spectral lines, we find asymmetric, subsonic uni-directional flows, with velocity maxima of ≈?80 km?s^?1 near the footpoints. The loops are highly inclined with respect to the vertical, by 55^○ and 70^○, respectively; thus the true height of the loop tops from the photospheric level is ≈?20^′′, comparable to the isothermal scale height.     

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.     

The Oscillations of Coronal Loops Including the Shell

We investigate the MHD waves in a double magnetic flux tube embedded in a uniform external magnetic field. The tube consists of a dense hot cylindrical cord surrounded by a co-axial shell. The plasma and the magnetic field are taken to be uniform inside the cord and also inside the shell. Two slow and two fast magnetosonic modes can exist in the thin double tube. The first slow mode is trapped by the cord, the other is trapped by the shell. The oscillations of the second mode have opposite phases inside the cord and shell. The speeds of the slow modes propagating along the tube are close to the tube speeds inside the cord and the shell. The behavior of the fast modes depends on the magnitude of Alfvén speed inside the shell. If it is less than the Alfvén speed inside the cord and in the environment, then the fast mode is trapped by the shell and the other may be trapped under the certain conditions. In the opposite case when the Alfvén speed in the shell is greater than those inside the cord and in the environment, then the fast mode is radiated by the tube and the other may also be radiated under certain conditions. The oscillation of the cord and the shell with opposite phases is the distinctive feature of the process. The proposed model allows to explain the basic phenomena connected to the coronal oscillations: i) the damping of oscillations stipulated in the double tube model by the radiative loss, ii) the presence of two different modes of perturbations propagating along the loop with close speeds, iii) the opposite phases of oscillations of modulated radio emission, coming from the near coronal sources having sharply different densities.     

Magnetic Stereoscopy of Coronal Loops in NOAA 8891

The Solar TErrestrial RElations Observatory (STEREO) requires powerful tools for the three-dimensional (3D) reconstruction of the solar corona. Here we test such a program with data from SOHO and TRACE. By taking advantage of solar rotation, a newly developed stereoscopy tool for the reconstruction of coronal loops is applied to the solar active region NOAA 8891 observed from 1 March to 2 March 2000. The stereoscopic reconstruction is composed of three steps. First, we identify loop structures in two TRACE images observed from two vantage viewpoints approximately 17 degrees apart, which corresponds to observations made about 30 hours apart. In the second step, we extrapolate the magnetic field in the corona with the linear force-free field model from the photospheric line-of-sight SOHO/MDI data. Finally, combining the extrapolated field lines and one-dimensional loop curves from two different viewpoints, we obtain the 3D loop structures with the magnetic stereoscopy tool. We demonstrate that by including the magnetic modeling this tool is more powerful than pure geometrical stereoscopy, especially in resolving the ambiguities generated by classical stereoscopy. This work will be applied to the STEREO mission in the near future.