Alfvénic waves in polar spicules

Tavabi, E.; Koutchmy, S.; Ajabshirizadeh, A.; Maralani, A. R. Ahangarzadeh; Zeighami, S.

doi:10.1051/0004-6361/201423385

Cited by 18 publications

(14 citation statements)

References 47 publications

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“…It is observed that Type-II spicules have axial-rotation spin with rotation speeds of 25-30 km s -1 (De Pontieu et al 2012). From analysis of the proper motions in Type-II spicules at the limb in a polar coronal hole in a Hinode/SOT Ca II H movie, Tavabi et al (2015) have recently presented evidence that the spin is from untwisting of the magnetic field like the untwisting we observe in our big jets. Moore et al (2011) proposed that Type-II spicules are miniature versions of the large EUV/X-ray jets in coronal holes, made in the same way by interchange reconnection of emerging and blowout-erupting granule-size closed magnetic bipoles ( 1000 km in diameter) with the ambient feet of the coronal magnetic field rooted in the magnetic network in quiet regions and corona holes.…”

Section: Summary and Disscussionmentioning

confidence: 56%

“…See Moschou et al (2013) for evidence of an upward force in large jets observed in AIA He II 304 Å movies.] Another candidate for the energy-transfer process is turbulent cascade of the wave to Alvenic waves of progressively higher wavenumbers, finally dissipating at the high-wavenumber end of the cascade to heat the plasma in the cascading turbulence (e.g., Hollweg 1984;van Ballegooijen et al 2011). We expect that physically realistic numerical modeling of the generation and non-linear propagation of the magnetic-untwisting waves in polar coronal jets will be required to establish how these waves lose energy in the inner corona.…”

Section: Summary and Disscussionmentioning

confidence: 99%

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Magnetic Untwisting in Solar Jets That Go Into the Outer Corona in Polar Coronal Holes

Moore

Sterling

Falconer

2015

ApJ

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We study 14 large solar jets observed in polar coronal holes. In EUV movies from SDO/AIA, each jet appears similar to most X-ray jets and EUV jets that erupt in coronal holes, but each is exceptional in that it goes higher than most, so high that it is observed in the outer corona beyond 2.2 R Sun in images from the SOHO/LASCO/C2 coronagraph. From AIA He II 304 Å movies and LASCO/C2 running-difference images of these high-reaching jets, we find: (1) the front of the jet transits the corona below 2.2 R Sun at a speed typically several times the sound speed; (2) each jet displays an exceptionally large amount of spin as it erupts; (3) in the outer corona, most of the jets display measureable swaying and bending of a few degrees in amplitude; in three jets the swaying is discernibly oscillatory with a period of order 1 hour. These characteristics suggest that the driver in these jets is a magnetic-untwisting wave that is basically a large-amplitude (i.e., non-linear) torsional Alfven wave that is put into the reconnected open field in the jet by interchange reconnection as the jet erupts. From the measured spinning and swaying we estimate that the magnetic-untwisting wave loses most of its energy in the inner corona below 2.2 R Sun . We point out that the torsional waves observed in Type-II spicules might dissipate in the corona in the same way as the magnetic-untwisting waves in our big jets and thereby power much of the coronal heating in coronal holes.

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Section: Summary and Disscussionmentioning

confidence: 56%

Section: Summary and Disscussionmentioning

confidence: 99%

Magnetic Untwisting in Solar Jets That Go Into the Outer Corona in Polar Coronal Holes

Moore

Sterling

Falconer

2015

ApJ

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“…The solar corona contains transverse, incompressible oscillations in the magnetic field and plasma velocity (Banerjee et al 1998;Tomczyk et al 2007;Jess et al 2009;McIntosh 2012), but whether they should be called "Alfvén waves" is still a matter of debate (e.g., Mathioudakis et al 2013). More specifically, spicules and jets themselves seem to contain torsional or kink motions that could have an Alfvénic character (Kukhianidze et al 2006;De Pontieu et al 2014b;Tavabi et al 2015). There is also evidence for longitudinal compressive wavesi.e., fluctuations in density and the velocity component parallel to the wavenumber vector-that may or may not follow the ideal MHD magnetoacoustic dispersion relations (Ofman et al 1999;Krishna Prasad et al 2012;Threlfall et al 2013;Miyamoto et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Driving Solar Spicules and Jets With Magnetohydrodynamic Turbulence: Testing a Persistent Idea

Cranmer

Woolsey

2015

ApJ

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The solar chromosphere contains thin, highly dynamic strands of plasma known as spicules. Recently, it has been suggested that the smallest and fastest (Type II) spicules are identical to intermittent jets observed by the Interface Region Imaging Spectrograph. These jets appear to expand out along open magnetic field lines rooted in unipolar network regions of coronal holes. In this paper we revisit a thirty-year-old idea that spicules may be caused by upward forces associated with Alfvén waves. These forces involve the conversion of transverse Alfvén waves into compressive acoustic-like waves that steepen into shocks. The repeated buffeting due to upward shock propagation causes nonthermal expansion of the chromosphere and a transient levitation of the transition region. Some older models of wave-driven spicules assumed sinusoidal wave inputs, but the solar atmosphere is highly turbulent and stochastic. Thus, we model this process using the output of a time-dependent simulation of reduced magnetohydrodynamic turbulence. The resulting mode-converted compressive waves are strongly variable in time, with a higher transition region occurring when the amplitudes are large and a lower transition region when the amplitudes are small. In this picture, the transition region bobs up and down by several Mm on timescales less than a minute. These motions produce narrow, intermittent extensions of the chromosphere that have similar properties as the observed jets and Type II spicules.

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“…One may interpret these components as the components of a rotating spicule. Twisty motions have already been reported with a velocity of about 25 kms -1 (De Pontieu et al 2014a;Tavabi et al 2015b) and they are predicted by magnetic vortex plasma simulation (Kitiashvili et al 2013;Gonzalez-Aviles et al 2017). An explosive event could eject plasma in all directions and produce equal red-and blueshifts, as for a bi-directional jets (Tavabi et al 2015a).…”

Section: Discussionmentioning

confidence: 77%

Chromospheric Peculiar Off-limb Dynamical Events from IRIS Observations

Tavabi

Koutchmy

2019

ApJ

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To study motions and oscillations in the solar chromosphere and at the transition region (TR) level we analyze some extreme Doppler shifts observed off-limb with the Interface Region Imaging Spectrograph (IRIS). Raster scans and slit-jaw imaging observations performed in the near-ultraviolet (NUV) channels were used. Large transverse oscillations are revealed by the far wings profiles after accurately removing the bulk average line profiles of each sequence. Different regions around the Sun are considered. Accordingly, the cool material of spicules is observed in Mg II lines rather dispersed up to coronal heights. In the quiet Sun and especially in a polar coronal hole, we study dynamical properties of the dispersed spiculesmaterial off-limb using a high spectral, temporal and spatial resolutions IRIS observations. We suggest that numerous smallscale jet-like spicules show rapid twisting and swaying motions evidenced by the large distortion and dispersion of the line profiles, including impressive periodic Doppler shifts. Most of these events repeatedly appear in red-and blue-shifts above the limb throughout the whole interval of the observation datasets with an average swaying speed of order ±35 kms -1 reaching a maximum value of 50 km s -1 in the polar coronal hole region, well above the 2.2 Mm heights. We identified for the 1 st time waves with a short period of order of 100 sec and less and transverse amplitudes of order of ± 20 to 30 km s -1 with the definite signature of Alfven waves. No correlation exists between brightness and Doppler shift variations; the phase speed of the wave is very large and cannot definitely be determined from the spectral features seen along the quasi-radial features. Even shorter periods waves are evidenced, although their contrast is greatly attenuated by the overlapping effects along the line of sight.

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Alfvénic waves in polar spicules

Cited by 18 publications

References 47 publications

Magnetic Untwisting in Solar Jets That Go Into the Outer Corona in Polar Coronal Holes

Magnetic Untwisting in Solar Jets That Go Into the Outer Corona in Polar Coronal Holes

Driving Solar Spicules and Jets With Magnetohydrodynamic Turbulence: Testing a Persistent Idea

Chromospheric Peculiar Off-limb Dynamical Events from IRIS Observations

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