Structure, Stability, and Evolution of Magnetic Flux Ropes From the Perspective of Magnetic Twist

Li, Rui; Kliem, B.; Titov, V. S.; Chen, Jun; Wang, Yuming; Wang, Haimin; Liu, Chang; Xu, Yan; Wiegelmann, T.

doi:10.3847/0004-637x/818/2/148

Cited by 265 publications

(325 citation statements)

References 100 publications

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“…A "weighted optimization" method 47,48 is then applied to derive the NLFFF, from which magnetic field lines are computed. Physical properties of field lines, such as the magnetic twist, can be further deduced 49 .…”

Section: Methodsmentioning

confidence: 99%

High-resolution observations of flare precursors in the low solar atmosphere

et al. 2017

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Solar flares are generally believed to be powered by free magnetic energy stored in the corona 1 , but the build up of coronal energy alone may be insufficient for the imminent flare occurrence 2 . The flare onset mechanism is a critical but less understood problem, insights into which could be gained from small-scale energy releases known as precursors, which are observed as small pre-flare brightenings in various wavelengths (e.g., refs 3-13 ), and also from certain small-scale magnetic configurations such as the opposite polarity fluxes [14][15][16] , where magnetic orientation of small bipoles is opposite to that of the ambient main polarities. However, high-resolution observations of flare precursors together with the associated photospheric magnetic field dynamics are lacking. Here we study precursors of a flare using unprecedented spatiotemporal resolution of the 1.6 m New Solar Telescope, complemented by novel microwave data. Two episodes of precursor brightenings are initiated at a small-scale magnetic channel 17-20 (a form of opposite polarity fluxes) with multiple polarity inversions and enhanced magnetic fluxes and currents, lying near the footpoints of sheared magnetic loops. The low-atmospheric origin of these precursor emissions is corroborated by microwave spectra. We propose that the emerging magnetic channel field interacts with the sheared arcades to cause precursor brightenings at the main flare core region. These high-resolution results provide evidence of low-atmospheric small-scale energy release and possible relationship to the onset of the main flare.We study the 22 June 2015 M6.5 flare (SOL2015-06-22T18:23) using Hα (line-center and red-wing) images and photospheric vector magnetograms obtained by the recently commissioned 1.6 m New Solar Telescope (NST) 21, 22 at Big Bear Solar Observatory (BBSO), which is stabilized by a high-order adaptive optics (AO) system (see Methods). In particular, the vector field data is taken by the Near InfraRed Imaging Spectropolarimeter (NIRIS) 23 at the 1.56µ Fe I line. These observations have the highest spatial resolution ever achieved for the solar observations (∼70 km for Hα and ∼170 km for vector field) and rapid cadence (28 s for Hα and 87 s for vector field). Also used are flare microwave spectra and time profiles from the new Expanded Owens Valley Solar Array (EOVSA; see Methods), and time profiles of hard X-ray (HXR) and soft X-ray (SXR) fluxes from the Reuven Ramaty High Energy Solar Spectroscopic Imager (RHESSI) 24 and the Geostationary Operational Environmental Satellite (GOES)-15, respectively. Ancillary data of full-disk corona images and magnetograms from the Solar Dynamics Observatory (SDO) 25 are additionally used. The long-duration 22 June 2015 M6.5 flare occurred near the disk center (8• W, 12• N) at NOAA active region (AR) 12371. Time profiles of flare emissions in different wavelengths (including HXR, SXR, and microwave) clearly display that soon before the flare impulsive phase starting from ∼17:51 UT, there are two short ep...

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Section: Methodsmentioning

confidence: 99%

High-resolution observations of flare precursors in the low solar atmosphere

et al. 2017

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“…A magnetic flux rope, characterized by magnetic fields twisted about a common axis, may become unstable and act as a driver for an eruption (e.g., Amari et al 1999;Török & Kliem 2005).Aflux rope can be identified using a combination of topological measures deduced from the employed NLFF models, e.g., in the form of the twist number T w and the squashing factor Q (Liu et al 2016b). T w gives the number of turns by which two infinitely approaching field lines, i.e., two neighboring field lines whose separation could be arbitrarily small, wind around each other, and it is computed by where α is the force-free parameter, dl is the length increment along a magnetic field line, and L is the length of the field line (Berger & Prior 2006;Liu et al 2016b).…”

Section: Methodsmentioning

confidence: 99%

The Causes of Quasi-homologous CMEs

Liu

Wang

et al. 2017

ApJ

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In this paper, we identified the magnetic source locations of 142 quasi-homologous (QH) coronal mass ejections (CMEs), of which 121 are from solar cycle (SC) 23 and 21 from SC 24. Among those CMEs, 63% originated from the same source location as their predecessor (defined as S-type), while 37% originated from a different location within the same active region as their predecessor (defined as D-type). Their distinctly different waiting time distributions, peaking around 7.5 and 1.5hr for S-and D-type CMEs, suggest that they might involve different physical mechanisms with different characteristic timescales. Through detailed analysis based on nonlinear forcefree coronal magnetic field modeling of two exemplary cases, we propose that the S-type QH CMES might involve a recurring energy release process from the same source location (by magnetic free energy replenishment), whereas the D-type QH CMEs can happen when a flux tube system is disturbed by a nearby CME.

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“…However, we would also emphasise that a direct comparison between values of t w and the twist given by the angle of footpoint rotation relative to axis footpoints, even in relatively simple cases, can be complex and potentially misleading (as shown in Appendix A, and discussed further in e.g. Liu et al (2016)). …”

Section: Overlying Flux Rope: Twist and Helicitymentioning

confidence: 99%

“…This is the definition used by Hood and Priest (1979) when analysing the kink instability. The link between this definition of twist and the integral expression t w (which is the value of the force-free parameter, α, times the length of the field line) is often unclear (see the detailed theoretical comparison in Appendix C of Liu et al, 2016, and the discussion therein). We practically demonstrate how these two quantities are linked in the simple case of a straight cylindrical, force-free loop, which allows the two expressions to be evaluated analytically and directly compared.…”

Section: Appendix A: Comparison Of Twist Measuresmentioning

confidence: 99%

Flux Rope Formation Due to Shearing and Zipper Reconnection

2018

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Zipper reconnection has been proposed as a mechanism for creating most of the twist in the flux tubes that are present prior to eruptive flares and coronal mass ejections. We have conducted a first numerical experiment on this new regime of reconnection, where two initially untwisted parallel flux tubes are sheared and reconnected to form a large flux rope. We describe the properties of this experiment, including the linkage of magnetic flux between concentrated flux sources at the base of the simulation, the twist of the newly formed flux rope, and the conversion of mutual magnetic helicity in the sheared pre-reconnection state into the self-helicity of the newly formed flux rope.

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Structure, Stability, and Evolution of Magnetic Flux Ropes From the Perspective of Magnetic Twist

Cited by 265 publications

References 100 publications

High-resolution observations of flare precursors in the low solar atmosphere

High-resolution observations of flare precursors in the low solar atmosphere

The Causes of Quasi-homologous CMEs

Flux Rope Formation Due to Shearing and Zipper Reconnection

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