High-energy Electrons and Electric Currents during a Flare
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Revision as of 12:56, 19 June 2015
Nugget | |
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Number: | 255 |
1st Author: | Sophie Musset, |
2nd Author: | Nicole Vilmer and Véronique Bommier |
Published: | 22 June 2015 |
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Contents |
Introduction
Energy release during solar flares is likely to occur on coronal current sheets, which can be traced by their photospheric footprints (current ribbons measured at the photospheric level). What is the relation between the locations of these photospheric current ribbons and the X-ray sources tracing the energetic electrons during solar flares? Nowadays, the combination of continuous polarimetric measurements with SDO/HMI and hard X-ray observations with RHESSI allows to compare high quality vector magnetic field (and electric current density) maps and HXR observations of solar flare at the same time. The relation between photospheric current densities and X-ray emission and their simultaneous evolution have been studied for the X2.2 flare on February 15 2011.
The X-ray Flare
The X2.2 flare of February 15, 2011 is appropriate for this kind of study since it happened near the disk center, which allows good measurements of the vector magnetic field and reduce the projection effects. The RHESSI corrected count rates and the X-ray flux from GOES for the flare are presented in figure 1.
Images were reconstructed with the CLEAN algorithm using detectors 2 to 9, at times shown by the vertical dotted lines in figure 1, which correspond to peaks in the high energy emission (> 25 keV).
The photospheric magnetic field and vertical current-density maps
Spectropolarimetric data from SDO/HMI allows the calculation of the full 3D vector magnetic field at the photospheric level. We used the UNNOFIT inversion and Metcalf disambiguation codes to calculate the vector magnetic field. The map obtained for the active region (11158) at 01:48 UT is shown on figure 2 (left). Then the vertical current density at the photospheric level is calculated from the curl of the magnetic field. The corresponding map is shown on figure 2 (right).
The X2.2 flare of February 15, 2011 is appropriate for this kind of study since it happened near the disk center, which allows good measurements of the vector magnetic field and reduce the projection effects. The RHESSI corrected count rates and the X-ray flux from GOES for the flare are presented in figure 1.
HMI produce a set of spectropolarimetric data every 12 minutes, and we thus have access to a full vector magnetic map every 12 minutes. The maps closest in time to the peak of the X-ray flare are at 01:48:00 and 02:00:00 UT (see dashed-dotted vertical lines in figure 1). We can therefore study the evolution of the photospheric magnetic field and vertical current density during the flare.
The two magnetic maps at 01:48 and 02:00 are shown in figure 3. The current ribbons are clearly visible (the long and narrow current density structures between the two central magnetic polarities of the active region). These current ribbons are most likely the photospheric footprints of a coronal current sheet where magnetic reconnection can occur.
The vertical magnetic field does not show a significant evolution between these two maps, however, the vertical current density is evolving during the 12-minute gap between the two maps. In particular, the current density increases of 15% in the region marked by the red box on figure 3.
Hard X-ray-emitting electrons and photospheric currents
Figure 4 show the evolution of hard X-ray sources with time, overlaid on the vertical magnetic field and current density maps at the photospheric level obtained at 01:48 UT (left) and 02:00 UT (right).
The X-ray sources are evolving during the flare and their structure is quite complex. The 50-100 keV source labelled A in intervals (a), (b) and (c) is most likely to be a coronal X-ray source. The 50-100 keV sourced labelled D’ and E in intervals (d) and (e) are the footpoints of a loop.
Two main results can be drawn from the superposition of X-ray emissions sites on the magnetic maps:
1. Part of the X-ray emissions produced in an extended coronal source in intervals (a), (b) and (c) overlay the current ribbons observed at the photospheric level;
2. The new X-ray source D’ appearing at 50-100 keV in intervals (d) and (e) is located in the region where new vertical photospheric electric currents appeared between 01:48 and 02:00 UT. This observation shows a a clear link between particle acceleration and current ribbons, which trace reconnecting current sheets.
These two results can be qualitatively explained in the magnetic reconnection scenario, where magnetic reconnection is most likely to occur on current sheets in the corona. Since X-ray emissions are the signatures of particle acceleration and since photospheric currents trace the footprints of coronal current sheets, spatial and temporal correlation between these X-ray emitting sites and photospheric current ribbons can be expected. In addition, the evolution of magnetic reconnection sites on the course of the flare may lead to two linked consequence: the apparition of new sites of hard X-ray emissions and a change in the magnetic topology leading to an increase of the vertical current density at the photospheric level.
Conclusion
These observations show a spatial correlation between photospheric current ribbons and coronal X-ray sources. Moreover, for the first time, a conjoint evolution of hard X-ray emission and vertical current density at the photospheric level is observed during the course of a flare, and explained as the double consequence of the propagation of reconnection sites in the corona.
References
RHESSI Nugget Date | 22 June 2015 + |
RHESSI Nugget First Author | Sophie Musset, + |
RHESSI Nugget Index | 255 + |
RHESSI Nugget Second Author | Nicole Vilmer and Véronique Bommier + |