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Helicity Thinkshop on Solar Physics 12-17 October Beijing. Injection of m a gnetic helicity and chirality c hange in sunspot penumbral filaments. Jiangtao Su N ational Astronomical Observatories of China. Outline. Introduction: magnetic helicity injection (MHI) and solar activities;
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Helicity Thinkshopon Solar Physics12-17October Beijing Injection of magnetic helicity and chirality change in sunspot penumbral filaments Jiangtao Su National Astronomical Observatories of China
Outline • Introduction: magnetic helicity injection (MHI) and solar activities; • A initial study of relationships between MHI and major flares; • MHI and chirality change of penumbral filaments in the magnetic polarity inversion line (PIL) region.
Introduction • Magnetic helicity is ameasure of twists, kinks, and interlinkagesof magnetic field lines (Berger & Field 1984); It is almost preserved on a timescale less than the global diffusion time scale; • Because of this conservation property, it has been suggested that Coronal Mass Ejections (CMEs) are needed to avoid the endless helicity accumulation in the corona (Rust 1994, 2001;Low 1996; Kusano et al. 2004; Zhang and Low 2005); • Zhang et al. (2006)conjectured there is an upper bound on the total magnetic helicity that a force-free field can contain. Thus, the accumulation of magnetic helicity in excess of this upper bound would initiate a CME;
Recent theoretical work by Amari et al. (2003)suggests that a large enough helicity is a necessary but not sufficient condition for an ejection to occur, and this is supported by the observational work of Nindos & Andrews (2004); • Whether or not that the coronahelicity accumulation is important to the origin and initiation of CMEs is still hotly in debate(Spicer et al. 2003; Rust 2003; Rust & LaBonte 2005;Phillips et al. 2005); • Therefore, knowledge of the magnetic helicity budgets in the solar active regions is essential for clarifying this issue (Green et al. 2002; Démoulin et al. 2002; Nindos et al. 2003; Mandrini et al. 2004; Georgoulis and LaBonte 2007); • Untill now, the fundamental cause of solar flares is unkown, but Andrews (2003) has shown that virtually all X-class flares produce a coronal mass ejection (CME); • Recently, LaBonte et al. (2007) found a necessary condition for the occurrence of an X-flare is that the peak helicity flux has a magnitude > 6×1036 Mx2 s-1, which should be an important flare index used for big flare prediction;
Moon et al. (2002a,b) believed that the sharp helicity change occurring over short timescales (half hour) can be a significant factor in triggering flares; • Zhang et al. (2008) also found a sharp variation of the transport rate of magnetic helicity in AR 10930 during a X3.4 flare; • Kusano et al. (2003) proposed annihilation of magnetic helicity as a triggering mechanism for solar flares. If the helicity is sharply reversed within a magnetic arcade, reconnection quickly grows in the helicity inversion layer, driving explosive dynamics; • Yokoyama et al. (2003) studied flare activities in AR 8100 and found that most of the flare events occurred about half a day after the helicity injection rate changed its sign;
However, Sakurai & Hagino (2003) studied two X-class flares ARs and found the total magnetic helicity evolved slowly and did not show abrupt changes at the time of the flares; • People have found during the flares, the profile of the spectral line being used for the magnetic measurements is distorted and the pulsive helicity changes were spurious (Qiu & Gary2003; Hartkorn & Wang 2004, e.g.); • Park et al. (2008) investigated the variation of magnetic helicity around the times of 11 X-class flares. They found each of these major flares was preceded by a significant helicity accumulation and the helicity accumulates at a nearly constant rate then becomes nearly constant before the flares.
In this work, we revisit the relationships between rate of MHI and major x-class flares. With the Hinode data, we find a close relationship between MHI and chirality change in sunspot penumbral filaments.
dHm/dtand major x-class flares List of the major flares • Data: MDI/SOHO 96 minute longitudinal magnetograms; • Method: Local Correlation Tracking (LCT, Chae et al. 2001) used to calculate dHm/dt.
A X5.7 occurred on 2000 July 14 NOAA 9077 Before and after the x5.7 flare, the MHI rate evolves in a direction to decrease the magnitde of the previous MHI rate. The helicity accumulates at a nearly constant rate (Park 2008), then becomes nearly constant after the flares. For this kind of constant rate, Magara & Tsuneta (2007) thought it is a saturation of helilcity transport.
A X1.3 occurred on 2001 Oct 25 NOAA 9672 Same as NOAA 9077, but the magnitude of helicity injection rate first decreased, then increased.
X18 on 2003 Oct 28 NOAA 10486 After the X18 flare, the helicity injection rate evolves in a direction to decrease the magnitde of the previous MHI rate
X4.1 on 2005 Jan 17 NOAA 10720 After the flare, the MHI rate changed its sign. It is similar to the active region of NOAA 8100(Yokoyama et al. 2003).
After (or before and after) the major flare, the MHI rate may evolve in a direction to decrease the magnitde of the pre-flare MHI rate. The expression for dHm/dtincluding two terms are: The first term in Eq.is usually associated to magnetic flux emergence, whereas the second is associated to shearing/twisting motions. Which one is more important for the above evolutions?
For NOAA 10930, three regions are selected to calculate dHm/dt: (1) Frame1: large negative sunspot; (2) Frame2: two sunspots; (3) Frame3: small positive sunspot. Frames 1 and 3 exclude the magnetic PIL region; NOAA 10930
PIL region = Frame2 - Frame1+Frame3 dhm/dt in PIL region should be nearly equal to the one in Frame2 extracting those in Frames 1 and 3. After the flare, the MHI rate in Frames 1 and 3 did not change much, while that in Frame2 evolves in a direction to decrease the magnitde of the previous MHI rate and at last change its sign, which was mainly caused by the change of MHI rate in PIL region.
Magra & Tsuneta (2007) Using the formula for the MHI rate Magra & Tsuneta (2007) and have obtained the similar results.
MHI and chirality change in sunspot penumbral filaments in NOAA 10930 Averged αz in large positive sunspot Averaged αz in small negative sunspot X3.4 flare Su et al. (2009) The penumbral filaments changing their chirality occurred in the rising stage of averged αz (MHI).
Chirality change in the filaments of the PIL region in NOAA 10930 Chirality changed from right- to left-handedness
Right-handedfilaments Left-handed filaments
Splitting of a right-handed filament Dec-10 Expanding Birth of a left-handed Filament Shrinking Dec-11
4 5 Filament screw pinch varying At Cut4 pinch increasing: 396 , 475, and 1030 km; At Cut5 pinch decreasing: 2580, 1988, and 806 km.
Total positive helicity decreased while total negative helicity increased.
Counter-clockwise rotation of the positive sunspot could inject negative helicity to the corona, which may directly lead to the filament change their chirality.
Evidences of chirality change of the Filaments • Untwisting of penumbral filaments: The expansion of a filament, the separation of the features, and the increase of the screw pinch. 2. Chirality change of the filaments: The shrinking of a filament, the convergence of the features, and the decrease of the screw pinch. • Positive helicity decreased while negative helicity increased in response to a sunspot rotating, which injected negative helicity to the corona (photosphere).
Thanks for your attention!