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1.
本文详细分析了1974年9月10日白光耀斑的光谱资料,并利用Non-LTE理论计算了它的半经验大气模型和辐射损失。由光谱测量得到:(1)连续辐射强度在巴耳末系限(3647)附近发生跳跃。在极大时刻,巴耳末跳跃可达约11%;(2)该耀斑有强而宽的巴耳末谱线发射,其高项巴耳末谱线轮廓的全半宽随主量子数n而变化,在8<n<9达到极小;(3)连续辐射极大时刻同微波爆发极大相一致,比Ha耀斑极大时刻提前几分钟。这三个特征很可能是Ⅰ类白光耀斑的典型特征。 相似文献
2.
本分析了南京大学太阳塔1991年10月24日用多波段光谱仪观测到的高时间分辨率(5s)的一个2N/X2.1级白光耀斑光谱,对耀斑谱线轮廓,连续发射强度,X射线和射电爆发资料进行了综合对比,分析表明,该耀斑属I类白光耀斑,具有如下特征:(1)在白光耀斑的脉冲相期间,各波段光谱线心强度,连续辐射,谱线半宽以及线翼红不对称性与硬X射线高能波段的爆分同时达到极大;(2)Hα谱线在连续发射极大时半宽达10 相似文献
3.
本文分析了南京大学太阳塔1991年10月24日用多波段光谱仪观测到的高时间分辨率(5s)的一个2N/X2.1级白光耀斑光谱.对耀斑谱线轮廓、连续发射强度、X射线和射电爆发资料进行了综合对比,分析表明,该耀斑属Ⅰ类白光耀斑,具有如下特征:(1)在白光耀斑的脉冲相期间,各波段光谱线心强度、连续辐射、谱线半宽以及线翼红不对称性与硬X射线高能波段的爆发同时达到极大;(2)H_a谱线在连续发射极大时半宽达10A,且呈现强烈的线心反转,H_β和H_γ线心亦有反转;(3)所拍摄的5条谱线都有明显的红不对称性,持续时间约为1分钟,根据上述结果,本文用电子束轰击、色球蒸发和色球压缩区对该耀斑能量积聚和释放的动力学机制作了定性的分析和解释。 相似文献
4.
白光耀斑是第22周太阳活动峰的一个重要研究课题。本文扼要地探讨了白光耀斑的研究近况,针对目前尚未解决的白光耀斑连续发射起源问题,提出了色球凝聚可能对应产生白光连续辐射增强的新观点。 相似文献
5.
白光耀斑研究近年来获得较大进展,对其连续发射起源机制目前流行三种解释.一是耀斑形成过程中所产生的色球凝聚[1-3],二是非热粒子注入大气致氢原子非热激发和电离[4-6],三是色球强加热所引起的对大气深层的辐射反加热[7].这三类解释具有一个共性,即除了自身直接对连续谱 相似文献
6.
通过对比分析TRACE195A和RHESSI的X射线及Ha的图像,发现2002年7月23日的X4.8级耀斑的主体是一个典型的双带耀斑,它的Ha及TRACE195A的图像都显现出明显的双带耀斑特征,TRACE195A的像还呈现一个环拱结构,其环拱的足点与TRACE的亮带并不重合,但TRACE的亮带与X射线像的位置对应很好.在耀斑极大时刻附近,大于38keV的X射线像呈现一个低的环跨在TRACE的双带上,X射线环的顶点及两足点尤其明显,在这个低的环上方,还存在一个在低能量段明显的X射线日冕源,对该耀斑的空间结构及演化特征作了描述,还简单地讨论了一个可能的理论解释. 相似文献
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8.
本文简要地介绍了发生于2545MHZ和2645MHZ频率上的一次与白光耀斑共生的微波射电大爆发,该爆发有很高的峰值流量,很高的偏振和很复杂的偏振状态的变化,同时该爆发的第一主峰期间同时观测到色球层白光耀斑连续辐射,本文还简要地讨论了这次射电爆发与色球白光耀斑的时间演化关系及射电爆发在主峰期间偏期间偏振状态急剧变化的原因。 相似文献
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10.
分析了2个耀斑事件。这2个耀斑事件都具有双带结构,并伴有耀斑环顶部位置的硬X射线(HXR)辐射,这个辐射源我们称为环顶源。在文章中,通过求亮度重心的方法,我们对耀斑双带的相对运动,以及HXR环顶源的高度变化进行了分析。结果表明:耀斑相偶亮核间距离的时间曲线,与HXR亮度曲线具有相反的相关性,亮核间距离在HXR流量上升阶段会减少;与此同时,HXR环顶源的高度会下降。而通常的相偶亮核的分离运动以及环顶源的上升运动发生在极大相之后。 相似文献
11.
Using high cadence, high resolution near infrared (NIR) observations of the X10 white‐light flare (WLF) on 2003 October 29, we investigated the evolution of the core‐halo structure of white‐light emission during the two‐second period flare peak. We found that size and intensity of the halo remained almost constant in the range of 10 Mm2. However, the core area was very compact and expanded rapidly from about 1 Mm2 to 4 Mm2. At the same time, the total emission of the core increased nearly twenty times. This distinct behavior indicates that different heating mechanisms might be responsible for core and halo emissions. In addition to the temporal analysis, we compared the intensity enhancements of the flare core and halo. The result shows that the halo contrast increased by about 8% compared to the flare‐quiet region, which could be explained by a combination of direct‐heating and backwarming models (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
12.
We study the hysteresis effect between the solar flare index and cosmic ray intensity for the past 37 years from January 1, 1965 to December 31, 2001 on a daily basis. We show that smoothed time series of flare index and the daily Calgary Galactic Cosmic Ray intensity values exhibit significant solar cycle dependent differences in their relative variations during the studied period. The shapes of these differences vary from cycle to cycle. So we investigate the momentary time lags between the two time series for the odd and even cycles. 相似文献
13.
Fiber – or intermediate drift – bursts are a continuum fine structure in some complex solar radio events. We present the analysis of such bursts in the X17 flare on 28 Oct. 2003. Based on the whistler wave model of fiber bursts we derive the 3D magnetic field structures that carry the radio sources in different stages of the event and obtain insight into the energy release evolution in the main flare phase, the related paths of nonthermal particle propagation in the corona, and the involved magnetic field structures. Additionally, we test the whistler wave model of fiber bursts for the meter and the decimeter wave range. Radio spectral data (Astrophysikalisches Institut Potsdam, Astronomical Observatory Ond?ejov) show a continuum with fibers for ≈?6 min during the main flare phase. Radio imaging data (Nançay Radio Heliograph) yield source centroid positions of the fibers at three frequencies in the spectrometer band. We compare the radio positions with the potential coronal magnetic field extrapolated from SOHO/MDI data. Given the detected source site configuration and evolution, and the change of the fiber burst frequency range with time, we can also extract those coronal flux tubes where the high-frequency fiber bursts are situated even without decimeter imaging data. To this aim we use a kinetic simulation of whistler wave growth in sample flux tubes modeled by selected potential field lines and a barometric density model. The whistler wave model of fiber bursts accurately explains the observations on 28 Oct. 2003. A laterally extended system of low coronal loops is found to guide the whistler waves. It connects several neighboring active regions including the flaring AR 10486. For varying source sites the fiber bursts are emitted at the fundamental mode of the plasma frequency over the whole range (1200?–?300 MHz). The present event can be understood without assuming two different generation mechanisms for meter and decimeter wave fiber bursts. It gives new insight into particle acceleration and propagation in the low flare and post-CME corona. 相似文献
14.
Min Wang Rui-Xiang Xie Chun Xu Shuo-Biao Shi Yi-Hua Yan National Astronomical Observatories Yunnan Observatory Chinese Academy of Sciences Kunming National Astronomical Observatories Chinese Academy of Sciences Beijing 《中国天文和天体物理学报》2005,5(5):508-518
We present a, large complex radio burst and its associated fast tune structures observed on 2001 April 10 in the frequency range of 0.65-7.6 GHz. The NoRH radio image observation shows very complex radio source structures which include preexisting, newly emerging, submerging/cancelling polarities and a bipolar, a tripolar (a 'bipolar + remote unipolar'), and a quadrupolar structure. This suggests that the radio burst is generated from a very complicated loop structure. According to the spectral and image observations, we assume that the beginning of this flare was caused by a single bipolar loop configuration with a 'Y-type' re-connection structure. A composite of radio continuum and fast time structures is contained in this flare. The various fast radio emission phenomena include normal and reverse drifting type III bursts, and slowly drifting and no-drift structures. The tripolar configurations may form a double-loop with a 'three-legged' structure, which is an important source of the various types of fast time structures. The two-loop reconnection model can lead simultaneously to electron acceleration and corona heating. We have also analyzed the behaviors of coronal magnetic polarities and the emission processes of different types radio emission qualitatively. Interactions of a bipolar or multi-polar loop are consistent with our observational results. Our observations favor the magnetic reconnection configurations of the 'inverted Y-type' (bipolar) and the 'three-legged' structures (tripolar or quadrupolar). 相似文献
15.
对3个超级活动区(大的δ型黑子群)NOAA 5395、6659、6891中的电流分布作了系统计算;利用已发表的计算方法,首次用于实际活动区的水平电流分布;给出了电流与耀斑核的关系。将这种关系分为两类:密切相关和准相关,并同时给出了统计结果。结果显示:1)对于垂直电流和水平电流来说,密切相关率分别是29%和10%,准相关率分别是50%和30%;2)有些耀斑核与两种电流都相关,而大多数只与其中一种相关;3)与两种电流都不相关的耀斑核只占6%左右;4)两种电流起互补作用,因而对于预报耀斑具有一定的作用。通过分析还发现,磁场剪切强的地方相应于强的垂直电流,而磁中性线附近纵向磁场梯度大的地方相应于强的水平电流。 相似文献
16.
Horizontal proper motions were measured with local correlation tracking (LCT) techniques in active region NOAA 11158 on 2011 February 15 at a time when a major (X2.2) solar flare occurred. The measurements are based on continuum images and magnetograms of the Helioseismic and Magnetic Imager on board the Solar Dynamics Observatory. The observed shear flows along the polarity inversion line were rather weak (a few 100 m s–1). The counter‐streaming region shifted toward the north after the flare. A small circular area with flow speeds of up to 1.2 km s–1 appeared after the flare near a region of rapid penumbral decay. The LCT signal in this region was provided by small‐scale photospheric brigthenings, which were associated with fast traveling moving magnetic features. Umbral strengthening and rapid penumbral decay was observed after the flare. Both phenomena were closely tied to kernels of white‐light flare emission. The white‐light flare only lasted for about 15 min and peaked 4 min earlier than the X‐ray flux. In comparison to other major flares, the X2.2 flare in active region NOAA 11158 only produced diminutive photospheric signatures (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
17.
Neupert效应的定性描述是耀斑中脉冲分量(硬X射线、微波暴)与渐变分量(软X射线发射)之间存在的因果关系,即耀斑最初的能量是以加速粒子的形式释放,加速的电子在大气传输过程中产生非热硬X射线轫致辐射,并加热大气,耀斑软X射线发射是高能粒子注入大气的响应.根据经典Neupert效应的定量描述,硬X射线发射(表征非热电子注入)结束时软X射线应该立刻达到极大,但以往的观测发现一些耀斑软X射线峰值时间(t2)明显晚于硬X射线结束时间(t1)(τ=t2–t1,τ 0),热与非热辐射之间存在明显的偏离经典Neupert效应的情况.为了研究偏离经典Neupert效应的事件,在2002—2015年间的RHESSI (Reuven Ramaty High Energy Solar Spectroscopic Imager)和GOES (Geostationary Operational Environmental Satellites)耀斑列表中,按照在25–50 keV范围内光变较简单、软X射线有对应发射峰等判据,共选择276个耀斑样本,统计了这些耀斑的τ分布、环长d (用双足点源之间的距离来表征)与τ的关系.结果显示:(1)有227个耀斑τ 0,即有约82%的耀斑偏离经典Neupert效应;(2)τ与d之间存在一定的线性相关,即环越长,软X射线极大的时间越延后;(3)似乎存在一个临界距离,当环长小于临界距离时,经典Neupert效应成立.这些结果印证了修正Neupert效应的必要性,并对其物理意义进行了讨论. 相似文献
18.
L. V. Didkovsky D. L. Judge A. R. Jones S. Wieman B. T. Tsurutani D. McMullin 《Astronomische Nachrichten》2007,328(1):36-40
The solar irradiance in the Extreme Ultraviolet (EUV) spectral bands has been observed with a 15 s cadence by the SOHO Solar EUV Monitor (SEM) since 1995. During remarkably intense solar flares the SEM EUV measurements are saturated in the central (zero) order channel (0.1–50.0 nm) by the flare soft X‐ray and EUV flux. The first order EUV channel (26–34 nm) is not saturated by the flare flux because of its limited bandwidth, but it is sensitive to the arrival of Solar Energetic Particles (SEP). While both channels detect nearly equal SEP fluxes, their contributions to the count rate is sensibly negligible in the zero order channel but must be accounted for and removed from the first channel count rate. SEP contribution to the measured SEM signals usually follows the EUV peak for the gradual solar flare events. Correcting the extreme solar flare SEMEUV measurements may reveal currently unclear relations between the flare magnitude, dynamics observed in different EUV spectral bands, and the measured Earth atmosphere response. A simple and effective correction technique based on analysis of SEM count‐rate profiles, GOES X‐ray, and GOES proton data has been developed and used for correcting EUV measurements for the five extreme solar flare events of July 14, 2000, October 28, November 2, November 4, 2003, and January 20, 2005. Although none of the 2000 and 2003 flare peaks were contaminated by the presence of SEPs, the January 20, 2005 SEPs were unusually prompt and contaminated the peak. The estimated accuracy of the correction is about ±7.5% for large X‐class events. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim) 相似文献
19.
Lin Wang Cheng Fang Ming-De Ding 《中国天文和天体物理学报》2007,7(5):721-732
We analyze an M9.1 two-ribbon solar flare which occurred on 2004 July 22 us- ing the TRACE white-light and 1700A~。images,the RHESSI,and the SOHO/MDI data.We find many small-scale fast-varying brightenings that appeared in the white-light and 1700A~。images along the flare ribbons.Some of them underwent rapid motions in weak magnetic field regions.We identify these short-lived brightenings as UV continuum enhancement.Our preliminary result shows that the brightenings are closely related to the HXR emission.They have a lifetime of 30-60 s and a typical size of about 1″-2″.The intensity enhancement is about 150-200 times the mean value of the quiet-Sun.According to previous works,we infer that the 1700A~。enhancement may be dominated by the increased emission of 1680 A con- tinuum coming from the temperature minimum region.The impulsive feature in the 1700 A~。light curves of the small-scale brightenings may be due to the irradiation of the impulsive CIV line intensity caused by the bombardment of non-thermal electron beams. 相似文献
20.
It was found that in the spectrum of the white-light flare on 11 October, 1974, at the time of continuum maximum, the intensity of K1 in the Caii K line increased very significantly and reached nearly half of the continuum intensity. The duration of this unusual increase is less than 4 min. It seems that existing semi-empirical models can reproduce neither this characteristic nor the chromospheric condensation. 相似文献