Signatures of Magnetic Reconnection at the Footpoints of Fan-shaped Jets on a Light Bridge Driven by Photospheric Convective Motions

Bai, Xianyong; Socas‐Navarro, H.; Nóbrega-Siverio, Daniel; Su, Jiangtao; Deng, Yangbo; Li, D.; Cao, Wenda; Ji, Kaifan

doi:10.3847/1538-4357/aaf1d1

Cited by 26 publications

(22 citation statements)

References 66 publications

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“…Numerical simulations and IRIS and SDO observations have revealed the peculiar magnetic-field configuration in light bridges that leads to reconnection . IRIS observations have also elucidated the cross-field coherence in dynamic evolution of these lightwalls, which has been associated with slipping reconnection (Hou et al, 2016b;Bai et al, 2019): the light-wall dynamics appear to be intimately tied to, and thus help reveal the overall changes in, magnetic topology during a flare. High-resolution spatial and temporal data from IRIS and SDO have been used to confirm the observation of signatures of magnetic reconnection and accompanying flux cancelation (Yang et al, 2018b) including two-loop interaction processes, plasma blob ejections, and sheet-like structures above the flux-cancelation sites.…”

Section: Magnetic Reconnection Mechanisms In the Low Solar Atmospherementioning

confidence: 99%

“…IRIS observations have been used to study their propagation and the evolution of non-linear harmonics as they travel upwards (Chae et al, 2018), as well as their frequency-dependent damping in sunspot umbrae (Krishna Prasad et al, 2017). Shock waves have also been studied (using coordinated data from DST or Hinode) in sunspot light bridges, with their provenance tied to magnetic reconnection and leakage of photospheric waves (Tian et al, 2018a;Bai et al, 2019). Similar processes have been invoked to explain the presence of high-frequency signals discovered in active-region plage (Narang et al, 2019).…”

Section: Observationsmentioning

confidence: 99%

“…Evidence of such emission was independently found in the IRIS Si IV lines by Nóbrega-Siverio et al (2017) and Guglielmino, Young, and Zuccarello (2019). Other examples of chromospheric ejections with associated TR emission observed with IRIS are fan-shaped jets originating from light bridges (Yang et al, 2015;Bharti, 2015;Bai et al, 2019) and penumbral microjets Humphries et al, 2020), although penumbral microjets are not genuine jets with significant mass motions, but rather manifestations of heat fronts (Esteban Buehler et al, 2019; Rouppe van der Voort and Drews, 2019; Drews and Rouppe van der Voort, 2020). In order to properly understand the TR emission of the aforementioned phenomena, one has to take the highly dynamic nature of the chromosphere into account as well as the fact that some elements in the TR have long ionization and recombination timescales, leading to relevant non-equilibrium ionization effects (e.g.…”

Section: Solar Jets and Surgesmentioning

confidence: 99%

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A New View of the Solar Interface Region from the Interface Region Imaging Spectrograph (IRIS)

et al. 2021

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The Interface Region Imaging Spectrograph (IRIS) has been obtaining near- and far-ultraviolet images and spectra of the solar atmosphere since July 2013. IRIS is the highest resolution observatory to provide seamless coverage of spectra and images from the photosphere into the low corona. The unique combination of near- and far-ultraviolet spectra and images at sub-arcsecond resolution and high cadence allows the tracing of mass and energy through the critical interface between the surface and the corona or solar wind. IRIS has enabled research into the fundamental physical processes thought to play a role in the low solar atmosphere such as ion–neutral interactions, magnetic reconnection, the generation, propagation, and dissipation of waves, the acceleration of non-thermal particles, and various small-scale instabilities. IRIS has provided insights into a wide range of phenomena including the discovery of non-thermal particles in coronal nano-flares, the formation and impact of spicules and other jets, resonant absorption and dissipation of Alfvénic waves, energy release and jet-like dynamics associated with braiding of magnetic-field lines, the role of turbulence and the tearing-mode instability in reconnection, the contribution of waves, turbulence, and non-thermal particles in the energy deposition during flares and smaller-scale events such as UV bursts, and the role of flux ropes and various other mechanisms in triggering and driving CMEs. IRIS observations have also been used to elucidate the physical mechanisms driving the solar irradiance that impacts Earth’s upper atmosphere, and the connections between solar and stellar physics. Advances in numerical modeling, inversion codes, and machine-learning techniques have played a key role. With the advent of exciting new instrumentation both on the ground, e.g. the Daniel K. Inouye Solar Telescope (DKIST) and the Atacama Large Millimeter/submillimeter Array (ALMA), and space-based, e.g. the Parker Solar Probe and the Solar Orbiter, we aim to review new insights based on IRIS observations or related modeling, and highlight some of the outstanding challenges.

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Section: Magnetic Reconnection Mechanisms In the Low Solar Atmospherementioning

confidence: 99%

Section: Observationsmentioning

confidence: 99%

Section: Solar Jets and Surgesmentioning

confidence: 99%

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A New View of the Solar Interface Region from the Interface Region Imaging Spectrograph (IRIS)

et al. 2021

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“…The structures mentioned above are usually derived from local inhomogeneous magnetic field and magneto-convection, indicating the complexity of sunspot magnetic and thermal properties (Spruit & Scharmer 2006;Schüssler & Vögler 2006;Rimmele 2008;Rempel et al 2009;Reardon et al 2013). As a result of the deviation from sunspot background conditions, various dynamic phenomena especially surge-like activities frequently occur around these structures, such as surges and light walls above the light bridges (Roy 1973;Asai et al 2001;Shimizu et al 2009;Louis et al 2014a;Yang et al 2015Yang et al , 2016Yang et al , 2017Bharti 2015;Robustini et al 2016;Hou et al 2016aHou et al ,b, 2017Zhang et al 2017;Tian et al 2018;Bai et al 2019), transient jets above a penumbral filament intrusion into the umbra (Bharti et al 2017), and ubiquitous penumbral microjets in the penumbral chromosphere (Katsukawa et al 2007b;Jurčák & Katsukawa 2008;Nakamura et al 2012;Tiwari et al 2016;Drews & Rouppe van der Voort 2017;Samanta et al 2017;Esteban Pozuelo et al 2019; Rouppe van der Voort & Drews 2019). These surge-like activities display an impressive variety of morphological, temporal, and spectral properties.…”

Section: Introductionmentioning

confidence: 99%

Sunspot penumbral filaments intruding into a light bridge and the resultant reconnection jets

Hou

Zhong

et al. 2020

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Context. Penumbral filaments and light bridges are prominent structures inside sunspots and are important for understanding the nature of sunspot magnetic fields and magneto-convection underneath. Aims. We investigate an interesting event where several penumbral filaments intrude into a sunspot light bridge. In doing so we aim to gain further insight into the magnetic fields of the sunspot penumbral filament and light bridge, as well as their interaction. Methods. Combining data from the New Vacuum Solar Telescope, Solar Dynamics Observatory, and Interface Region Imaging Spectrograph, we study the emission, kinematic, and magnetic topology characteristics of the penumbral filaments intruding into the light bridge and the resultant jets. Results. At the west part of the light bridge, the intruding penumbral filaments penetrate into the umbrae on both sides of the light bridge, and two groups of jets are also detected. The jets share the same projected morphology with the intruding filaments and are accompanied by intermittent footpoint brightenings. Simultaneous spectral imaging observations provide convincing evidence for the presences of magnetic-reconnection-related heating and bidirectional flows near the jet bases and contribute to measuring the vector velocities of the jets. Additionally, nonlinear force-free field extrapolation results reveal strong and highly inclined magnetic fields along the intruding penumbral filaments, highly consistent with the results deduced from the vector velocities of the jets. Therefore, we propose that the jets could be caused by magnetic reconnections between emerging fields within the light bridge and the nearly horizontal fields of intruding filaments. The jets are then ejected outward along the stronger filament fields. Conclusions. Our study indicates that magnetic reconnection could occur between the penumbral filament fields and emerging fields within the light bridge and produce jets along the stronger filament fields. These results further complement the study of magnetic reconnection and dynamic activities within the sunspot.

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“…So far, their formation mechanism is not fully understood. Data observed by Goode Solar Telescope, IRIS, Spectro-polarimeter/Hinode and AIA/SDO enabled Bai et al (2019) to study the dynamical properties of fan-like light bridges. The Hα −0.8 Å images revealed the propagation of ribbon-like brightenings along the light bridges which they considered as evidence of slipping reconnection.…”

Section: Observational Evidence Of Magnetic Reconnection In the Solarmentioning

confidence: 99%

Magnetic Reconnection in the Solar Corona

Kumar¹,

Wang²

2019

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Magnetic reconnection, a ubiquitous process in space plasmas, is currently cutting-edge research. This process is usually referred to as the topological reconstruction of the magnetic field in plasmas. Magnetic reconnection in the solar corona has become widely accepted as a key mechanism responsible for the occurrence of solar eruptions such as solar flares and coronal mass ejections. The magnetic energy released in this process is further converted to thermal and kinetic energy which lead to an acceleration of the particles. Hence, research in magnetic reconnection is crucial to better understand the physical mechanisms that trigger solar eruptive events. The present review article particularly focuses on the steady-state MHD theory of slow as well as fast magnetic reconnection and presents observational evidence for magnetic reconnection found in space-based data.

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Signatures of Magnetic Reconnection at the Footpoints of Fan-shaped Jets on a Light Bridge Driven by Photospheric Convective Motions

Cited by 26 publications

References 66 publications

A New View of the Solar Interface Region from the Interface Region Imaging Spectrograph (IRIS)

A New View of the Solar Interface Region from the Interface Region Imaging Spectrograph (IRIS)

Sunspot penumbral filaments intruding into a light bridge and the resultant reconnection jets

Magnetic Reconnection in the Solar Corona

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