Homologous large-scale activity in the solar eruptive events of November 24–26, 2000 I. M. Chertok a, V. V. Grechnev b, H. S. Hudson c, and N.V. Nitta.

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Homologous large-scale activity in the solar eruptive events of November 24–26, 2000 I. M. Chertok a, V. V. Grechnev b, H. S. Hudson c, and N.V. Nitta d a Solar Physics Divisions, IZMIRAN, Troitsk, Russia b Institute of Solar-Terrestrial Physics, Irkutsk, Russia c Space Sciences Laboratory, University of California, Berkeley, USA d Lockheed Martin Solar and Astrophysics Laboratory, Palo Alto, USA We study large-scale activity on the solar disk associated with a November 24–26, 2000 series of six recurrent major flares (see Table 1) and ‘halo’ coronal mass ejections (CMEs). The analysis is based mainly on the SOHO/EIT data, particularly by using properly rotated difference full-disk images with 12-min intervals at 195 Å as well as with 6-hour intervals at 171, 195, 284, and 304 Å. We demonstrate that these eruptive events were homologous not only by their flare and CME characteristics, as Nitta and Hudson [2001] showed, but also in terms of their large-scale CME-associated manifestations in the EUV corona. These include long and narrow channeled dimmings, some transequatorial; anisotropic coronal waves, propagating in a restricted angular sector; and additional quasi-stationary emitting fronts. As a whole, in all of these six events, the homologous CME-associated disturbances covered a considerable portion of the solar disk. The homology tendency appears to be due to significant disturbance, partial eruption and relatively fast restoration of the same large-scale structures involved in the repeating CME events. We briefly discuss the implications of the analysis in connection with the nature of coronal equilibrium. Such dynamic phenomena as dimmings and coronal waves are most pronounced on difference images. A realistic view of these CME-associated disturbances can be revealed by forming rotated fixed difference images. In this presentation, to avoid the appearance of false darkenings and brighenings, all SOHO/EIT disk images of the given event are rotated to a common pre-event time, and then the same pre-event image is subtracted from all subsequent heliograms. The image-rotation software is fully orthographic at the photosphere, i.e. the rotation is applied to the whole visible solar hemisphere and the spherical surface at the photospheric radius is rotated. This compensation for rotation is valuable even in working with the 195 Å data at 12-min cadence, because the image scale is the whole Sun. The orthographic projection is quite necessary in analysis of the 6-hour steps at 171, 284, and 304 Å [Chertok and Grechnev, 2003a,b]. Figure 1. H  (a), EUV (b,c), and soft X-ray (d) heliograms illustrating the situation on the disk at the onset of the events under consideration. The flaring active region AR 9236 is labeled 1. A central coronal hole (CH) and optical filament (F1) as well as a northwestern filament (F2) are denoted as well. The (b-d) are negative images for clarity. Conclusions. The analysis reported here demonstrates that this series of eruptive events was homologous not only in terms of the magnetic flux emergence around the preceding spot of the AR 1 and by the type of the flares and related halo CMEs, as noted in Paper I, but also from the characteristics of the accompanying large- scale activity displayed by SOHO/EIT data. First, in all six events, the CME-associated 195 Å dimmings are strongly anisotropic and can be observed in the form of analogous narrow and long channels (including transequatorial ones) extending throughout a large part of the disk southward and eastward of AR 1. Moreover, this characteristic pattern is visible in at least three of the EIT bands, namely the coronal ones. Second, practically all of the events were accompanied by similar, also anisotropic coronal waves that, in contrast to dimmings, propagated northward and northeastward of AR 1 in the same restricted angular sector. It means that in these events, not only AR 1 and its nearest outskirts, but also large-scale structures and areas were involved in the CME disturbances. The features we have described allow us to conclude that the CME-associated coronal disturbances were homologous and large-scale in nature. The rapid re-formation of these coronal structures suggests that some of the dimmings may not have resulted from the actual opening of coronal field into the solar wind. The opening of the field would imply an irreversible process. Instead the coronal restructurings we observe may have corresponded to partial eruptions, in which a homologous contraction followed the event-related expansion of the structure. The filament arcade south of the flaring active region provides a good example of this. We suggest that the mechanism for these reversible changes involves the transient perturbation of the global coronal force structure, which in equilibrium requires a balance of the magnetic forces, the solar wind, and gravity. This perturbation results from the magnetic restructuring restricted to the domains of the flare and CME. The occurrence of homologous distortions of the large-scale coronal field therefore suggests the presence of a robust equilibrium in these regions. We note that TRACE loop oscillations [Aschwanden et al., 1999] also sometimes seem to reflect the existence of a stable equilibrium state in regions near sites of sudden activity. Figure 2. SOHO/EIT fixed difference full-disk images at 195 Å, made by full orthographic rotation and re-projection of the images, showing the most developed large-scale dimmings (dark features) for all six events of the series. Figure 3. SOHO/EIT rotated difference full- disk images with 6-hour intervals showing large- scale dimming manifestations in event a of the series in the coronal lines 171, 195, 284 Å (b– d) and the transition- region line 304 Å (a). Figure 4. SOHO/EIT running difference full-disk images with 12-min intervals at 195 Å of all of six events showing homologous coronal waves (CW) and quasi- stationary emitting fronts (EF). Table 1. Positions and GOES fluxes of flare events of November 24-26, 2002 ID Day Peak, UT Longitude GOES a 24 05:02 W05 X2.0 b 24 15:13 W11 X2.3 c 24 22:00 W15 X1.8 d 25 09:20 W21 M3.5 e 25 18:45 W24 X1.9 f 26 16:48 W36 X4.0 Both the rotated fixed- and running-difference images and movies as well as some other data for all of six events under consideration, and the PFD file of the paper (to be published in JGR) are presented at the web site