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1.
张桂清 《中国天文和天体物理学报》1991,(4)
本文对六个活动区的同极磁流合并现象进行了分析,同极磁流合并可以分为两类。一类是在同极磁流合并之前,其间的异极性磁流很弱,它们的合并不是由于互相靠近而是由于相对延伸,另一类是在合并之前,其间有较强的异极性磁流,合并后有的明显靠近,有的则看不到靠近现象。高能耀斑与同极磁流合并有密切关系。6个活动区中发生的同极磁流合并几乎都与高能耀斑有关,这个结果可用于M和X级X射线耀斑的预报。文中还给出了用于预报的同极磁流合并的定义。 相似文献
2.
通过对活动区NOAA 6891中三个X级耀斑前后的向量磁场分析 ,研究耀斑发生条件与耀斑发生前后横向磁场和磁剪切变化的关系。我们发现与Hagyard的耀斑发生条件不同的是 ,强的横向磁场和磁剪切不是活动区中耀斑发生的充要条件。我们的结果表明 ,活动区NOAA 6891 1 991年 30日的耀斑发生在横向磁场和磁剪切剧烈下降后。尽管 1 0月 2 7日的耀斑发生后横向磁场和磁剪切变化很大 ,但由于有新磁流浮现 ,造成磁中性线的改变 ,使得横向磁场和磁剪切变化与耀斑发生的联系变得比较复杂。 相似文献
3.
本文研究了活动区5229中的H_β耀斑和磁场的关系。所用资料为北京天文台怀柔太阳观测站1988年11月13—18日期间获得的(时值活动区5229位于E40°W40°)。按活动区磁场演化情况,考察了新浮现磁流、磁剪切和磁对消与耀斑形成的关系。 图1a-1f给出了怀柔站观测到的11个H_β耀斑及87个耀斑核在纵向磁图上的情况。磁图以等高斯线形式给出,图中虚线表示负极,实线表示正极,等高斯线由外向内分别为20,40,80,160,320,640,960,1280,1600,1920,2240,2580,2800高斯。黑色小块表示Hβ耀斑核。其中有四分之三的Hβ耀斑核离开极性反变线的距离在10弧秒之内。发生在该活动区的耀斑超过80个,而怀柔站观测的仅是很小一部分。这对于耀斑建立过程的研究是很不够的,必需补充其他天文台的资料。注意到周报上已列出该活动区的软X射线(1~8A)M1.0级以上的高能耀斑事件,将它们补充进图1,用黑色三角形表示,画其位置时考虑到耀斑、黑子及磁特征之间的关系和它们彼此之间的时间差,并按Howard和Harvey给出的较差自转公式进行了改正。10个高能耀斑事件中有6个可能与磁特征N_3,N_7和P_2的衰减(即对消,另一极性在复杂活动区中衰减不明显)有关;另外的事件可能与发生在磁特征N_2、P_2之间的磁剪切有关。 相似文献
4.
黑子群快速的旋转(先反时针转,后顺时针转,质子耀斑前1—2天内旋转角度最大)、活动区强的SVC辐射、以及SVC和爆发峰值流量频谱的极大始终在8800MHz附近等与质子耀斑密切相关。同极性磁形中浮现或消失具有反极性的新磁流区域、磁场 相似文献
5.
通过对活动区NOAA6891中三个X线耀斑前后的向量磁场分析,研究耀斑发生条件与耀斑发生前后横向磁场和磁剪切变化的关系。我们发现与Hagyard的耀斑发生条件不同的是,强的横向磁场和磁剪切不是活动区中耀斑发生的充要条件。我们的结果表明,活动区NOAA6891 1991年30日的耀斑发生在横向磁场和磁剪切剧烈下降后。尽管10月27日的耀斑发生后横向磁场和磁剪切变化很大,但由于有新磁流浮现,造成磁中性 相似文献
6.
7.
用我国第一台高分辨光球——色球望远镜所取得的AR4811的高空间分辨(≤1″)的黑子和Hα色球照相资料分析了该活动区的精细结构的演化特征及有关耀斑活动。指出:(1)和当地原有磁场极性相同的新磁流的浮现在黑子群演化过程中起着阶段性的重要作用,但对活动区耀斑活动贡献不大。(2)有关暗条的各种频繁活动是当地耀斑的一种先兆。(3)活动区中相反极性磁场的相互挤压、剪切和旋转同时存在,是一个2B/M1.3级等一系列耀斑可能的储能机制。而与当地原有磁场极性相反的磁流环的浮现,是2B/M1.3级耀斑的可能触发因素。 相似文献
8.
本文研究了22周中的9个强质子耀斑活动区的共同特征,研究结果表明:单个团状结构黑子,即众多异极性黑子本影核紧锁在同一半影结构中的δ型黑子是强质子耀斑活动区的典型形态特征。黑子群的旋转是质子耀斑活动区的又一重要特征,黑子群的旋转方向与日面南、北半球无关。强质子耀斑的爆发总是在黑子群旋转角度达到正或负相极大之后出现。质子耀斑后,磁绳的松弛,黑子群可能会出现反向旋转,强的剪切过程和质子耀斑可能会再度出现。 相似文献
9.
赵爱娣 《紫金山天文台台刊》1992,11(2):69-74
本文对第22周以来产生M级以上(包括M级)的X射线耀斑的太阳黑子活动区进行了统计分析,得到如下结果:(1)黑子活动区在南北半球上分布是不均匀的。具体表现是:南半球出现的黑子活动区多于北半球出现的。南半球活动较强的黑子群主要集中在80°,160°,200°和340°经度附近;北半球活动较强的黑子群主要集中在240°-280°和340°-360°经度带。(2)黑子群的面积(S_p)越大越易产生X级的X射线耀斑。对黑子群面积S_p在大于1000,500-1000和小于500单位时,它们产生X级的X射线耀斑的比率分别约为41%,33%和9%。 相似文献
10.
1989年1月14日AR5312(怀柔编号89009)活动区,产生了一个2B级耀斑。该活动区经纬度为L306、S32,黑子群磁场分类为δ型。耀斑开始时间为0202UT,结束为0534UT,持续了3个多小时。北京天文台磁场望远镜,得到了一系列较完整的高分辨磁场及速度场资料,包括光球5324A的矢量磁场图和色球4861A的纵向磁场图(图1、2)。从耀斑前后的磁图得到以下结果: 1、耀斑初始亮点位于纵向磁场中性线附近高度剪切区域(见图1B区)、新浮磁流区(图2D区)以及双极磁结构对消区。前两种区域均能形成电流片,并且引起磁流体不稳定性,从而激发耀斑,但对消区和耀斑的关系不是很清楚,有待于理论工作者进一步探讨。 2、耀斑极大时间过后,光球和色球H_(11)=0线附近纵场梯度均有明显下降。 3、在强剪切区域(图1B区),5324A横向磁场和H_(11)=0线之间的夹角在耀斑极大时间过后有明显增大,该现象表明磁能释放后,磁场剪切缓解。 4、耀斑初始亮点产生后磁场高度剪切区、新浮磁流区和双极对消区,其触发耀斑的作用和周围的磁场环境有密切关系,特别是象具有磁海湾结构这样的活动区,似乎更容易产生耀斑。 5. 该活动区色球磁场位形,较光球磁场位形复杂,主要表现在:色球的纵场出现了一些磁弧岛结构,其原因可能是光球之上的磁力线高度剪切区及扭绞所致。0411 相似文献
11.
《天文和天体物理学研究(英文版)》2017,(8)
We analyze sunspot rotation and magnetic transients in NOAA AR 11429 during two X-class(X5.4 and X1.3)flares using data from the Helioseismic and Magnetic Imager on board the Solar Dynamics Observatory.A large leading sunspot with positive magnetic polarity rotated counterclockwise.As expected,the rotation was significantly affected by the two flares.Magnetic transients induced by the flares were clearly evident in the sunspots with negative polarity.They were moving across the sunspots with speed of order 3-7 km s~(-1).Furthermore,the trend of magnetic flux evolution in these sunspots exhibited changes associated with the flares.These results may shed light on understanding the evolution of sunspots. 相似文献
12.
The energy source of a flare is the magnetic field in the corona. A topological model of the magnetic field is used here for interpreting the recently discovered drastic changes in magnetic field associated with solar flares. The following observational results are self‐consistently explained: (1) the transverse field strength decreases at outer part of active regions and increases significantly in their centers; (2) the center‐of‐mass positions of opposite magnetic polarities converge towards the magnetic neutral line just after flares onset; (3) the magnetic flux of active regions decreases steadily during the course of flares. For X‐class flares, almost 50% events show such changes. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
13.
NOAA active region 6659, during its June 1991 transit across the solar disk, showed highly sheared vector magnetic field structures
and produced numerous powerful flares, including five white-light flares. Photospheric vector magnetograms of this active
region were obtained at the Huairou Solar Observing Station of the Beijing Astronomical Observatory. After the resolution
of the 180° ambiguity of the transverse magnetic field and transformation of off-center vector magnetograms to the heliographic
plane, we have determined the photospheric vertical current density and discussed the relationship with powerful flares. The
following results were obtained: (a) The powerful 3B/X12 flare on June 9, 1991 was triggered by the interaction between the
large-scale electric current system and magnetic flux of opposite polarity. (b) The kernels of the powerful Hβ flare (sites of the white-light flare) were close to the peaks of the vertical electric current density. (c) Some small-scale
structures of the vertical current relative to the magnetic islands of opposite polarity have not been found. This probably
implies that the electric current is not always parallel to the magnetic field in solar active regions. 相似文献
14.
The Tilt of the Magnetic Polarity Axis in Active Regions with Different Polarity Separation and Flux
In this paper, 203 bipolar active regions, in which bipolar magnetic fields are dominant, were chosen from the data set of photospheric vector magnetograms observed at Huairou Solar Observing Station in Beijing during 1988–1996. We calculated the tilts of the magnetic polarity axis in these active regions and investigated the dependence of the tilt on physical quantities such as polarity separation, total flux and the relationship between total flux and polarity separation, total area of active regions.The results are as follows:(1) The active regions with large tilt angle have smaller magnetic polarity separations.(2) The active regions with large tilt angle have smaller fluxes.(3) The active regions with large flux have larger polarity separations.(4) The active regions with large area have larger fluxes.These results will possibly provide new information about the nature and dynamic behavior of magnetic flux tubes forming active regions beneath the photosphere. 相似文献
15.
R. Chandra B. Schmieder C. H. Mandrini P. Démoulin E. Pariat T. Török W. Uddin 《Solar physics》2011,269(1):83-104
We present and interpret observations of two morphologically homologous flares that occurred in active region (AR) NOAA 10501
on 20 November 2003. Both flares displayed four homologous Hα ribbons and were both accompanied by coronal mass ejections
(CMEs). The central flare ribbons were located at the site of an emerging bipole in the centre of the active region. The negative
polarity of this bipole fragmented in two main pieces, one rotating around the positive polarity by ≈ 110° within 32 hours.
We model the coronal magnetic field and compute its topology, using as boundary condition the magnetogram closest in time
to each flare. In particular, we calculate the location of quasi-separatrix layers (QSLs) in order to understand the connectivity between the flare ribbons. Though several polarities were present in AR 10501,
the global magnetic field topology corresponds to a quadrupolar magnetic field distribution without magnetic null points.
For both flares, the photospheric traces of QSLs are similar and match well the locations of the four Hα ribbons. This globally
unchanged topology and the continuous shearing by the rotating bipole are two key factors responsible for the flare homology.
However, our analyses also indicate that different magnetic connectivity domains of the quadrupolar configuration become unstable
during each flare, so that magnetic reconnection proceeds differently in both events. 相似文献
16.
《New Astronomy》2017
The purpose of the present study is to investigate the association of solar energetic particle (SEP) events with halo coronal mass ejections (CME) and with their associated solar flares during the period 1997–2014 (solar cycle 23 and 24). We have found that halo CMEs are more effective in producing SEP events. The occurrence probability and peak fluxes of SEPs strongly depend on the halo CMEs speed (V) as follows. The highest associations, 56% for occurrence probability and 90% for average peak fluxes, are found for the halo CMEs with V> 1400 km s−1 but the lowest associations, 20% for occurrence probability and 5% for average peak fluxes, are found for halo CMEs with speed range 600 ≤ V ≤ 1000 km s−1. We have also examined the relationship between SEP events and halo CME associated solar flares and found that 73% of events are associated with western solar flares while only 27% are with eastern solar flares. For longitudinal study, 0–20° belt is found to be more dominant for the SEP events. The association of SEP events with latitudinal solar flares is also examined in the study. 51% of events are associated with those halo CMEs associated solar flares which occur in the southern hemisphere of the Sun while 49% are with those solar flares that occur in the northern hemisphere of the Sun. Also, 10–20° latitudinal belt is found to be likely associated with the SEP events. Further, 45% of SEP events are associated with M-class solar flares while 44% and 11% are with X and C-class respectively. Maximum number of SEP events are found for the fast halo CME associated X- class solar flares (68%) than M and C- class solar flares. 相似文献
17.
利用紫台赣榆站太阳精细结构望远镜拍摄的色球和光球照片,研究了1990年11月6日至13日NOAA6361活动区的磁位形演化和耀斑产生区域,发现该活动区的活动主要集中在11日和12日两天还观测到新老活动区的碰撞耦合及耦合界面处小纤维(fibril)的快速变化,这些现象是由于前导黑子之一的p1黑子的连续几天的运动造成的.所有的活动也主要集中在P1黑子的周围. 相似文献
18.
H. Zirin 《Solar physics》1970,14(2):328-341
A summary of data on the occurrence of flares and the development of active regions, based on cinematographic data is given. It is shown that flare frequency is determined by the orientation of the magnetic axis relative to the direction of solar rotation and the morphology of the magnetic field as seen in H. In particular, flares are most numerous in simple round spots with reversed polarity nearby, although they may also be frequent in complex spots with polarity reversal.Important solar active regions are shown to evolve principally along two lines; typically they appear as bright regions with loops and grow rapidly to stable bipolar magnetic form. Important activity will occur as the result of later growth of following polarity ahead of the main spots, or some other source of reversal. However, some groups appear as reversed polarity regions and grow rapidly to a level of extreme activity.A series of papers giving case histories is promised. 相似文献
19.
Maria D. Kazachenko Richard C. Canfield Dana W. Longcope Jiong Qiu 《Solar physics》2012,277(1):165-183
In order to better understand the solar genesis of interplanetary magnetic clouds (MCs), we model the magnetic and topological
properties of four large eruptive solar flares and relate them to observations. We use the three-dimensional Minimum Current Corona model (Longcope, 1996, Solar Phys.
169, 91) and observations of pre-flare photospheric magnetic field and flare ribbons to derive values of reconnected magnetic
flux, flare energy, flux rope helicity, and orientation of the flux-rope poloidal field. We compare model predictions of those
quantities to flare and MC observations, and within the estimated uncertainties of the methods used find the following: The
predicted model reconnection fluxes are equal to or lower than the reconnection fluxes inferred from the observed ribbon motions.
Both observed and model reconnection fluxes match the MC poloidal fluxes. The predicted flux-rope helicities match the MC
helicities. The predicted free energies lie between the observed energies and the estimated total flare luminosities. The
direction of the leading edge of the MC’s poloidal field is aligned with the poloidal field of the flux rope in the AR rather
than the global dipole field. These findings compel us to believe that magnetic clouds associated with these four solar flares
are formed by low-corona magnetic reconnection during the eruption, rather than eruption of pre-existing structures in the
corona or formation in the upper corona with participation of the global magnetic field. We also note that since all four
flares occurred in active regions without significant pre-flare flux emergence and cancelation, the energy and helicity that
we find are stored by shearing and rotating motions, which are sufficient to account for the observed radiative flare energy
and MC helicity. 相似文献
20.
We study the evolution of the active region (AR) NOAA 7321 in which appeared a so-called `neutral-line-associated source' (NLS) on the basis of data of the Nobeyama Radioheliograph and Yohkoh/SXT. We provide a physical interpretation of the NLS in terms of a topological magnetic reconnection model in a quadrupole magnetic configuration and discuss its relation to the evolution of the active region. Two kinds of the NLS were observed at 17 GHz. One of them, `rising NLS', was found in the growth stage. The other was `stationary NLS' detected in the maximal stage of the AR. Their presence was associated with substantial expansion of the active region's magnetosphere and accompanied by gradual development of spine-like structures visible in soft X-rays before homologous long-duration arcade flares. We suggest that the rising 17 GHz NLS corresponded to a fragment of a `horizontal' current sheet moving upward. Bright X-ray spines were boundaries of that current sheet. Almost all bursts observed from 26 to 28 October 1992 which accompanied class C and M flares occurred in the rising NLS. Formation of magnetic X-point singularities is believed to be responsible for the low-lying NLS. Reversal of circular polarization due to the effect of radio wave propagation was detected in that NLS on the limb. The initial stage of the microwave burst of the long-duration X9 class flare on 2 November 1992 occurred in this NLS. We also revealed observational manifestations of the presence of `vertical' non-neutral current sheet in the spatial structure of this NLS before the flare. 相似文献