Your search keyword '"SOHO/EIT OBSERVATIONS"' showing total 3 results

1. Two Quasi-periodic Fast-propagating Magnetosonic Wave Events Observed In Active Region NOAA 11167

Author

Ding Yuan, A. S. Kordi, Yu Liu, Yuhu Miao, Rehab Al-Shammari, A. Elmhamdi, Chaowei Jiang, Khaled Al-Mosabeh, and Yuandeng Shen

Subjects

010504 meteorology & atmospheric sciences, Flux, FOS: Physical sciences, Solar corona, Astrophysics, Magnetosonic wave, Astronomy & Astrophysics, EIT WAVES, 01 natural sciences, MORETON WAVES, Magnetohydrodynamics, EUV WAVES, 0103 physical sciences, OSCILLATIONS, Dispersion (water waves), SOLAR, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), 0105 earth and related environmental sciences, Physics, Science & Technology, Solar flare, Front (oceanography), Astronomy and Astrophysics, Coronal loop, Solar coronal waves, Solar extreme ultraviolet emission, Solar active regions, MHD WAVES, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Solar flares, Physical Sciences, SIMULATION, Space plasmas, ULTRAVIOLET IMAGING TELESCOPE, SOHO/EIT OBSERVATIONS, Event (particle physics)

Abstract

We report a detailed observational study of two quasi-periodic fast-propagating (QFP) magnetosonic wave events occurred on 2011 March 09 and 10, respectively. Interestingly, both the two events have two wave trains (WTs): one main and strong (WT-1) whereas the second appears small and weak (WT-2). Peculiar and common characteristics of the two events are observed, namely: 1) the two QFP waves are accompanied with brightenings during the whole stage of the eruptions; 2) both the two main wave trains are nearly propagating along the same direction; 3) EUV waves are found to be associated with the two events. Investigating various aspects of the target events, we argue that: 1) the second event is accompanied with a flux rope eruption during the whole stage; 2) the second event eruption produces a new filament-like (FL) dark feature; 3) the ripples of the two WT-2 QFP waves seem to result from different triggering mechanisms. Based on the obtained observational results, we propose that the funnel-like coronal loop system is indeed playing an important role in the two WT-1 QFP waves. The development of the second WT-2 QFP wave can be explained as due to the dispersion of the main EUV front. The co-existence of the two events offer thereby a significant opportunity to reveal what driving mechanisms and structures are tightly related to the waves., 9 figures,ApJ,accepted, December 19,2019

Published

2019

2. On-the-disk development of the halo coronal mass ejection on 1998 May 2

Author

Pohjolainen, S., Maia, D., Pick, M., Vilmer, N., Khan, J. I., Otruba, W., Warmuth, A., Benz, A., Alissandrakis, C., and Thompson, B. J.

Subjects

flares [sun], interplanetary shocks, uv radiation [sun], earth, solar-a mission, coronal mass ejections (cmes) [sun], radio, corona [sun], radio radiation [sun], signatures, soho/eit observations, origin, waves, x-ray telescope, x-rays, gamma rays [sun], flare

Abstract

A halo coronal mass ejection (CME) was observed at 15:03 UT on 1998 May 2 by the Solar and Heliospheric Observatory Large-Angle Spectrometric Coronagraph. The observation of the CME was preceded by a major soft X-ray flare in NOAA Active Region 8210, characterized by a delta spot magnetic configuration and some activity in region 8214. A large transequatorial interconnecting loop (TIL) seen in the soft X-rays connected AR 8210 to a faint magnetic field region in the periphery of region 8214. Smaller loop systems were also connecting AR 8210 to other fainter bipolar magnetic structures, the interconnecting loop (IL) east of AR 8210 being one of the most visible. We present here a multiwavelength analysis of the large- and small-scale coronal structures associated with the development of the flare and of the CME, with emphasis placed on radio-imaging data. In the early phases of the flare, the radio emission sources traced the propagation paths of electrons along the TIL and the IL, which are accelerated in the vicinity of AR 8210. Furthermore, jetlike flows were observed in soft X-rays and in H alpha in these directions. Significantly, the TIL and IL loop systems disappeared at least partially after the CME. An EUV Imaging Telescope (EIT) dimming region of similar size and shape to the soft X-ray TIL, but noticeably offset from it, was also observed. During the "flash" phase of the flare, new radio sources appeared, presenting signatures of destabilization and reconnection at discrete locations of the connecting loops. We interpret these as possible signatures of the CME liftoff on the disk. An H alpha Moreton wave (blast wave) and an "EIT wave" were also observed, originating from the flaring AR 8210. The signatures in radio, after the wave propagated high into the corona, include type II-like emissions in the spectra. The radio images link these emissions to fast-moving sources, presumably formed at locations where the blast wave encounters magnetic structures. The opening of the CME magnetic field is revealed by the radio observations, which show large and expanding moving sources overlying the later-seen EIT dimming region. Astrophysical Journal

Published

2001

3. 3D numerical experiment for EUV waves caused by flux rope eruption

Author

Rony Keppens, Y. Y. Li, Jing Ye, Zhixing Mei, Qiangwei Cai, and Xiaoyan Xie

Subjects

Shock wave, corona [Sun], MHD, Extreme ultraviolet lithography, Flux, chromosphere [Sun], Astrophysics, Astronomy & Astrophysics, EIT WAVES, 01 natural sciences, LARGE-SCALE WAVES, CORONAL MASS EJECTION, 0103 physical sciences, RECONNECTION, Astrophysics::Solar and Stellar Astrophysics, waves, 010306 general physics, 010303 astronomy & astrophysics, Physics, Science & Technology, SOLAR-FLARE WAVES, Astronomy and Astrophysics, shock waves, coronal mass ejections (CMEs) [Sun], EVOLUTION, MODEL, SHOCK-WAVES, Space and Planetary Science, Physics::Space Physics, Physical Sciences, SIMULATION, Magnetohydrodynamics, SOHO/EIT OBSERVATIONS, Rope

Abstract

We present a 3D magnetohydrodynamic numerical experiment of an eruptive magnetic flux rope (MFR) and the various types of disturbances it creates, and employ forward modelling of extreme ultraviolet (EUV) observables to directly compare numerical results and observations. In the beginning, the MFR erupts and a fast shock appears as an expanding 3D dome. Under the MFR, a current sheet grows, in which magnetic field lines reconnect to form closed field lines, which become the outermost part of an expanding coronal mass ejection (CME) bubble. In our synthetic SDO/AIA images, we can observe the bright fast shock dome and the hot MFR in the early stages. Between the MFR and the fast shock, a dimming region appears. Later, the MFR expands so its brightness decays and it becomes difficult to identify the boundary of the CME bubble and distinguish it from the bright MFR in synthetic images. Our synthetic images for EUV disturbances observed at the limb support the bimodality interpretation for coronal disturbances. However, images for disturbances propagating on-disc do not support this interpretation because the morphology of the bright MFR does not lead to circular features in the EUV disturbances. At the flanks of the CME bubble, slow shocks, velocity vortices and shock echoes can also be recognized in the velocity distribution. The slow shocks at the flanks of the bubble are associated with a 3D velocity separatrix. These features are found in our high-resolution simulation, but may be hard to observe as shown in the synthetic images.