螺旋结构日珥与Kippenhahn-Schlüter模型

利用具有螺旋结构的宁静日珥观测资料,基于:(1)日珥内部的磁场位形具有无力性质;(2)日珥整体电流性质可用Kippenhahn-Schlüter模型描述;从理论上探讨了这些日珥的电流特性。并将所得结果与Kuperus-Raadu日珥模型进行了比较,结果表明:(i)日珥内部的磁场和电流确实具有无力性质;(ii)不考虑虚镜电流的Kippenhahn-Schlüter模型可能是描述宁静日珥电流特性的较好模型;(iii)可能存在两类导致日珥爆发的物理原因。     

螺旋结构日珥爆发过程的物理本质

用Kuperus-Raadu模型描述日珥与背景场的互作用,Lundquist场描述日珥电流和磁场的分布,综合分析1980年8月18日爆发日珥的观测资料,讨论了该日珥爆发过程的物理本质。结果表明:(1)爆发日珥的物理原因是由于Lundouist场的kink不稳定性;(2)爆发过程中日珥磁能快速释放,从而导致电流强度不断减小,出现日珥上升并逐步趋于稳定;(3)日珥的爆发可能是导致CMEs的重要原因之一。      

龙卷日珥后期的环形结构内的物态分布

本文依据1990年8月29日龙卷状爆发日珥后期形成的环形结构形状,根据力平衡条件,求得了该环形结构内的运动速度、物质密度和磁场强度随环形弧长的分布,结果表明:在环的衰退期,环内物质由环顶向下运动基本上是一种在太阳重力作用下的自由下落运动;环内物质密度和磁场强度与环的形状密切相关。     

日冕物质抛射在太阳活动周期内的变化

本文利用SMM1980年和1984年观测的两组日冕物质抛射事件(CMF)及同期耀斑和爆发日珥观测资料,从速度、位置及活动相关率三个方面分析CME在这两个不同时期的特征,并由此推测它在整个太阳活动周内的变化趋势.     

2011年8月4日螺旋状日冕物质抛射爆发事件

利用多卫星多波段的综合观测数据,通过追踪光球表面等离子体速度分析计算了耀斑爆发前后磁螺度的变化,发现耀斑爆发前活动区中光球表面存在强的水平剪切运动,活动区磁螺度的注入主要由这种剪切运动所产生;使用CESE-MHD-NLFFF重建了耀斑爆发前后活动区的磁场位形,推测出耀斑过程中存在磁绳结构的抛射.基于这些分析,给出了这一螺旋状抛射结构的形成机制：爆发前暗条西侧足点的持续剪切运动驱动磁通量绳增加扭转,高度扭缠的通量绳与东侧足点附近的开放磁力线重联并与东侧足点断开,进而向外抛出并伴随解螺旋运动.另外,利用1AU处WIND卫星的观测数据在对应的行星际日冕物质抛射中找到典型磁云的观测特征.这表明除了传统上双足点均在太阳表面的磁云模型,这种单足点固定于太阳表面的磁通量绳爆发图景同样可能在行星系际空间形成磁云结构.研究结果对进一步认识磁云结构具有重要意义.     

日冕瞬变的观测特征和理论解释

本文综述了日冕瞬变现象的主要观测特征及其理论模型.日冕瞬变是从太阳日冕中向行星际空间大量抛出物质的过程,每次事件可有5×1015克的物质在103秒的时间内以约500公里/秒的典型速度被驱动流到日球中.日冕瞬变与太阳耀斑和爆发日珥事件有密切的相关性.作为一种新的太阳活动现象,近年来对日冕瞬变提出了许多理论解释.一种数值模拟方法将瞬变看成是由于热力学量或磁力在日冕底部的脉冲增长所产生的结果.许多分析模型认为是由磁环内部的电磁力或外部的磁压力驱动所致,或者是环中磁浮力驱动的结果.考虑到瞬变与耀斑和爆发日珥的相关性,活塞驱动模型认为,瞬变是稠密等离子体喷射,像活塞驱动机制.观测和理论都有待于进一步的研究.      

光卷日珥后期的环形结构内的物态分布

本文依据１９９０年８月２９日龙卷状爆发日珥后期形成的环形结构形状，根据力平衡条件，求得了该环形结构内的运动速度、物质密度和磁场强度随环形弧长的分布，结果表明：在环的衰退期，环内物质内环顶向下运动基本上是一种在太阳重力作用下的自由下落运动；环内物质密度和磁场强度与环的形状密切相关。     

掀起太阳神秘的面纱

太阳是我们唯一能观测到表面细节的恒星,我们直接观测到的太阳的大气层,从里向外分为光球、色球和日冕三层。就总体而言,太阳是一个稳定、平衡、发光的气体球,但它的大气层中有些地方却时常产生剧烈的运动,如黑子群的神秘出没、日珥的变化、耀斑的爆发。     

微波爆发前太阳射电发射的周期振荡

本文分析了1979年1月一12月紫台3.2cm、10cm波段上的爆发资料,峰值流量增量ΔS/S≥50%的爆发共计25个,发现所有25个爆发的爆前记录曲线上都存在着周期从几秒一10几秒、振幅约为太阳非扰动分量l%的振荡。这种振荡一般先于爆发几小时或几天。但对于特大爆发,如47GB型爆发,在长时间持续振荡以后,往往在爆前几十分钟或几小时突归宁静,呈平滑记录;对于较小的爆发,脉冲爆或持续期较短的复杂爆,如3S型、20GRF型以及45C型,在振荡同爆发之间不存在记录曲线的宁静时段,而往往由振荡直接延续到爆发。因此微波辐射的这种振荡特性可能是耀斑区域储能过程的一种反映。      

日冕扰动传播的数值模拟——(Ⅱ)热传导和辐射的影响

利用包含完全能量方程的磁流体力学方程组,数值研究了磁静力平衡基态下由于日面冷物质径向喷射所引起的日冕动力学响应。这些结果可以解释日珥的形成及伴随的日冕扰动传播。结果还表明,热传导和辐射损失对扰动传播的基本性质影响很小;对于日珥的形成,也未显出重要作用。      

Helicity evolution during the life cycle of tropical cyclones formed over the north Indian Ocean

Tropical cyclones (TCs) are violent multiscale convections occurring in the atmosphere. The destructive impact of the TCs is commensurate to the helicity associated with their evolution. The evolution of helicity of three TCs viz. Fani, Luban, and Ockhi formed over the north Indian ocean have been analyzed in this study. The analysis of kinetic energy density of primary (EP), secondary (ES) circulation and total helicity has shown that TCs showed helical features when the secondary overturning circulation knotted with primary tangential circulation in a moist convective situation. This condition can be considered a starting of the self-sustained helical feedback process. At this time, the core region became a rotation-dominated region that suppressed strain-dominated surroundings. The Okubo-Weiss parameter demonstrates the similar qualitative behavior of deep convection as total helicity. The local maximas in helicity time series are related with the changes in tropical cyclones' stages (intensification/dissipation). Therefore, consideration of helicity analysis is essential to analyze the TC intensification and dissipation.     

Observational study of magnetic chirality of solar active regions

We present the evolution of magnetic field and relationship with the magnetic (current) helicity in solar active regions from a series of photospheric vector magnetograms obtained at Huairou Solar Observing Station near Beijing, and also longitudinal magnetograms by MDI of SOHO, white light and 171 Å images by TRACE and soft X-ray images by Yohkoh.The conclusions in the analysis of the formation process of complex and delta magnetic configuration in some super active regions are the following: (1) The magnetic shear and gradient provide the non-potentiality of the magnetic field of active regions reflecting the existence of electric current. (2) Some of large-scale delta active regions could be due to the emergence of highly sheared non-potential magnetic flux bundles from the subatmosphere with amount of magnetic helicity, in addition to the emergence of twisted magnetic ropes. (3) We also present some results on the study of the magnetic (current) helicity in solar active regions.     

Large scale MHD properties of interplanetary magnetic clouds

Magnetic Clouds (MCs) are the interplanetary manifestation of Coronal Mass Ejections. These huge astrophysical objects travel from the Sun toward the external heliosphere and can reach the Earth environment. Depending on their magnetic field orientation, they can trigger intense geomagnetic storms. The details of the magnetic configuration of clouds and the typical values of their magnetohydrodynamic magnitudes are not yet well known. One of the most important magnetohydrodynamic quantities in MCs is the magnetic helicity. The helicity quantifies several aspects of a given magnetic structure, such as the twist, kink, number of knots between magnetic field lines, linking between magnetic flux tubes, etc. The helicity is approximately conserved in the solar atmosphere and the heliosphere, and it is very useful to link solar phenomena with their interplanetary counterpart. Since a magnetic cloud carries an important amount of helicity when it is ejected from the solar corona, estimations of the helicity content in clouds can help us to understand its evolution and its coronal origin. In situ observations of magnetic clouds at one astronomical unit are in agreement with a local helical magnetic structure. However, since spacecrafts only register data along a unique direction, several aspects of the global configuration of clouds cannot be observed. In this paper, we review the general properties of magnetic clouds and different models for their magnetic structure at one astronomical unit. We describe the corresponding techniques to analyze in situ measurements. We also quantify their magnetic helicity and compare it with the release of helicity in their solar source for some of the analyzed cases.     

Mass motions in a quiescent filament

The “disparition brusque” (DB) of a filament (N20, E35) has been observed above an active region with the Multichannel Subtractive Double Pass (MSDP) spectrograph operating on the Meudon Solar Tower, from 10h45 UT to 13h30 UT on June 22, 1981.Velocity fields and intensity fluctuations are measured in the Hα line. The DB doesn't take place simultaneously in all parts of the filament : thin threads (thickness <3 arc seconds) with upward radial velocities reaching about 50 km/s are successively observed inside the prominence from S to N regions. These motions correspond likely to the rise of material along magnetic loops closely related to the prominence structure. The dynamics inside such a magnetic loop is investigated : a high speed flow (supersonic, likely superalfvénic) strongly accelerated is evidenced and a deformation of the flux tube, probably due to the centrifugal forces exerted by the flow on the magnetic lines, is suggested.These results are compared with some theoretical works on dynamics inside magnetic loops, especially to siphon flow models. However, as in the case of the prominence support problem, better theoretical models are still needed.     

The role of helicity in the reconnection process

The change of helicity for magnetic reconnection is calculated with the help of a kinematic model. The results confirm the approximate conservation of magnetic helicity for reconnection in an almost ideal plasma as e. g. the solar corona. Different examples show the contributions of twist or linkage of flux tubes to the total helicity change in the process. However, they also show that helicity may be produced for reconnection processes in more extended non-ideal regions which is due to new magnetic flux linked to the reconnected flux tubes.     

Detailed analysis of dynamic evolution of three Active Regions at the photospheric level before flare and CME occurrence

We present a combined analysis of the applications of the weighted horizontal magnetic gradient (denoted as ${\mathit{WG}}_M$ in Korsós et al. (2015)) method and the magnetic helicity tool (Berger and Field, 1984) employed for three active regions (ARs), namely NOAA AR 11261, AR 11283 and AR 11429. We analysed the time series of photospheric data from the Solar Dynamics Observatory taken between August 2011 and March 2012. During this period the three ARs produced a series of flares (eight M- and six X-class) and coronal mass ejections (CMEs). AR 11261 had four M-class flares and one of them was accompanied by a fast CME. AR 11283 had similar activities with two M- and two X-class flares, but only with a slow CME. Finally, AR 11429 was the most powerful of the three ARs as it hosted five compact and large solar flare and CME eruptions. For applying the ${\mathit{WG}}_M$ method we employed the Debrecen sunspot data catalogue, and, for estimating the magnetic helicity at photospheric level we used the Space-weather HMI Active Region Patches (SHARP’s) vector magnetograms from SDO/HMI (Solar Dynamics Observatory/Helioseismic and Magnetic Imager). We followed the evolution of the components of the ${\mathit{WG}}_M$ and the magnetic helicity before the flare and CME occurrences. We found a unique and mutually shared behaviour, called the U-shaped pattern, of the weighted distance component of ${\mathit{WG}}_M$ and of the shearing component of the helicity flux before the flare and CME eruptions. This common pattern is associated with the decreasing-receding phases yet reported only known to be a necessary feature prior to solar flare eruption(s) but found now at the same time in the evolution of the shearing helicity flux. This result leads to the conclusions that (i) the shearing motion of photospheric magnetic field may be a key driver for solar eruption in addition to the flux emerging process, and that (ii) the found decreasing-approaching pattern in the evolution of shearing helicity flux may be another precursor indicator for improving the forecasting of solar eruptions.     

Study of magnetic flux emergence and related activity in active region NOAA 10314

We study the extremely complex active region (AR) NOAA 10314, that was observed from March 13–19, 2003. This AR was the source of several energetic events, among them two major (X class) flares, along a few days. We follow the evolution of this AR since the very first stages of its emergence. From the photospheric evolution of the magnetic polarities observed with SOHO/MDI we infer the morphology of the flux tube that originates the AR. Using a computation technique that combines Local Correlation Tracking with magnetic induction constrains, we compute the rate of magnetic helicity injection at the photosphere during the observed evolution. From our results we conclude that the AR originated by the emergence of a severely deformed magnetic flux tube having a dominantly positive magnetic helicity.     

A theoretical model for the magnetic helicity of solar active regions

Active regions on the solar surface are known to possess magnetic helicity, which is predominantly negative in the northern hemisphere and positive in the southern hemisphere. Choudhuri et al. [Choudhuri, A.R. On the connection between mean field dynamo theory and flux tubes. Solar Phys. 215, 31–55, 2003] proposed that the magnetic helicity arises due to the wrapping up of the poloidal field of the convection zone around rising flux tubes which form active regions. Choudhuri [Choudhuri, A.R., Chatterjee, P., Nandy, D. Helicity of solar active regions from a dynamo model. ApJ 615, L57–L60, 2004] used this idea to calculate magnetic helicity from their solar dynamo model. Apart from getting broad agreements with observational data, they also predict that the hemispheric helicity rule may be violated at the beginning of a solar cycle. Chatterjee et al. [Chatterjee, P., Choudhuri, A.R., Petrovay, K. Development of twist in an emerging magnetic flux tube by poloidal field accretion. A&A 449, 781–789, 2006] study the penetration of the wrapped poloidal field into the rising flux tube due to turbulent diffusion using a simple 1-d model. They find that the extent of penetration of the wrapped field will depend on how weak the magnetic field inside the rising flux tube becomes before its emergence. They conclude that more detailed observational data will throw light on the physical conditions of flux tubes just before their emergence to the photosphere.     

中性电流片的形成和环形日冕瞬变

在双极背景场下,光球层反向磁通量的喷发将会在新老磁场之间形成中性电流片.本文从理想磁流体方程组出发,考虑磁场和日冕等离子体的相互作用,对上述电流片的形成过程进行了数值研究.结果表明,对亚音速喷发,将由里向外形成四个区域:(1)由喷发物质直接形成的低温,高密度日珥,位于最里层;(2)紧挨抛射日珥的低温稀疏区;(3)喷发物质和日冕物质向中性电流片集中形成的高温.高密度物质环;(４)在环的周围,由快磁声波形成的,密度略比日冕背景为高的前鞘区.上述结构与典型的环形日冕瞬变的观测特征相符.由此表明双极背景场下反向磁通量的喷发可能是触发这类瞬变的重要机制.