Role of electron physics in the development of turbulent magnetic reconnection in collisionless plasmas

Daughton, W.; Roytershteyn, V.; Karimabadi, H.; Yin, L.; Albright, B. J.; Bergen, B.; Bowers, K. J.

doi:10.1038/nphys1965

Cited by 541 publications

(621 citation statements)

References 33 publications

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“…Particle-in-cell (PIC) simulations of small-scale reconnection by Daughton et al (2011) show that plasmoids and magnetic islands in 2D correspond to highly structured flux ropes in 3D. In the future, it will be important to couple these small-scale, fully kinetic simulations to larger scales where the resistive MHD approximation is more appropriate.…”

Section: Discussionmentioning

confidence: 99%

“…Pontin (2014a, 2014b) present simulations of null point reconnection that show the formation of flux ropes which are the 3D analogs of 2D magnetic islands. Fully kinetic 3D simulations by Daughton et al (2011) show that the current sheet develops into a tangled web of interconnected flux ropes, which is likely to also occur in 3D resistive MHD simulations. Over all, developing 3D model is the inevitable tendency, it is worth investing more effort in this issue in the future.…”

Section: Cs and Its Internal Fine Structures Observed In Numerical Exmentioning

confidence: 99%

“…6.1 and 6.3 of Priest and Forbes 2000, which described possible modes of instabilities that may develop in the CS, and more detailed features of a torn CS, respectively). In three dimensions, the current sheet develops flux ropes which are the counterpart of twodimensional magnetic islands (compare to Daughton et al 2011). The turbulence developing from the tearing mode enhances diffusion of the large-scale magnetic field.…”

Section: Reasonableness Of Large Values Of Cs Thickness and Resistivitymentioning

confidence: 99%

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Review on Current Sheets in CME Development: Theories and Observations

et al. 2015

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We introduce how the catastrophe model for solar eruptions predicted the formation and development of the long current sheet (CS) and how the observations were used to recognize the CS at the place where the CS is presumably located. Then, we discuss the direct measurement of the CS region thickness by studying the brightness distribution of the CS region at different wavelengths. The thickness ranges from 10 4 km to about 10 5 km at heights between 0.27 and 1.16 R from the solar surface. But the traditional theory indicates that the CS is as thin as the proton Larmor radius, which is of order tens of meters in the corona. We look into the huge difference in the thickness between observations and theoretical expectations. The possible impacts that affect measurements and results are studied, and physical causes leading to a thick CS region in which reconnection can still occur at a reasonably fast rate are analyzed. Studies in both theories and observations suggest that the difference between the true value and the apparent value of the CS thickness is not significant as long as the CS could be recognised in observations. We review observations that show complex structures and flows inside the CS region and present recent numerical modelling results on some aspects of these structures. Both observations and numerical experiments indicate that the downward reconnection outflows are usually slower than the upward ones in the same eruptive event. Numerical simulations show that the complex structure inside CS and its temporal behavior as a result of turbulence and the Petschek-type slow-mode shock could probably account for the thick CS and fast reconnection. But whether the CS itself is that thick still remains unknown since, for the time being, we cannot measure the electric current directly in that region. We also review the most recent laboratory experiments of reconnection driven by energetic laser beams, and discuss some important topics for future works.

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Section: Discussionmentioning

confidence: 99%

Section: Cs and Its Internal Fine Structures Observed In Numerical Exmentioning

confidence: 99%

Section: Reasonableness Of Large Values Of Cs Thickness and Resistivitymentioning

confidence: 99%

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Review on Current Sheets in CME Development: Theories and Observations

et al. 2015

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“…This is because in three dimensions, plasmoids are not bounded by flux surfaces in the 2-D system (see e.g. Daughton et al 2011). Still, this remains promising for further studies to understand the behaviour of the current volume and link it to observational consequences of reconnection (see § 4.3).…”

Section: Current Layers Associated With Flux Ropesmentioning

confidence: 99%

“…They are represented in two dimensions by nested magnetic field lines (see figure 17), while in three dimensions it is much more difficult to define what a plasmoid actually is. Indeed, in three dimensions, what would look like a coherent entanglement of field lines in one location may not be actually so different from the surrounding magnetic field in other locations in the 3-D volume, as discussed in § 3.3 (see for example the magnetic field rendering of the 3-D simulation in Daughton et al 2011;Nishida et al 2013). Recent numerical simulations such as by Baalrud, Bhattacharjee & Huang (2012), Wyper & Pontin (2014) provide invaluable tools to comprehend the link between 2-D and 3-D plasmoid dynamics.…”

Section: Plasmoids and Outflowsmentioning

confidence: 99%

Three-dimensional magnetic reconnection and its application to solar flares

Janvier

2017

J. Plasma Phys.

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Solar flares are powerful radiations occurring in the Sun's atmosphere. They are powered by magnetic reconnection, a phenomenon that can convert magnetic energy into other forms of energy such as heat and kinetic energy, and which is believed to be ubiquitous in the universe. With the ever increasing spatial and temporal resolutions of solar observations, as well as numerical simulations benefiting from increasing computer power, we can now probe into the nature and the characteristics of magnetic reconnection in three dimensions to better understand the phenomenon's consequences during eruptive flares in our star's atmosphere. We review in the following the efforts made on different fronts to approach the problem of magnetic reconnection. In particular, we will see how understanding the magnetic topology in three dimensions helps in locating the most probable regions for reconnection to occur, how the current layer evolves in three dimensions and how reconnection leads to the formation of flux ropes, plasmoids and flaring loops.

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The effect of a guide field on the structures of magnetic islands formed during multiple X line reconnections: Two‐dimensional particle‐in‐cell simulations

Huang

et al. 2014

JGR Space Physics

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A magnetic island plays an important role in magnetic reconnection. In this paper, using a series of two-dimensional particle-in-cell simulations, we investigate the magnetic structures of a magnetic island formed during multiple X line magnetic reconnections, considering the effects of the guide field in symmetric and asymmetric current sheets. In a symmetric current sheet, the current in the x direction forms a tripolar structure inside a magnetic island during antiparallel reconnection, which results in a quadrupole structure of the out-of-plane magnetic field. With the increase of the guide field, the symmetry of both the current system and out-of-plane magnetic field inside the magnetic island is distorted. When the guide field is sufficiently strong, the current forms a ring along the magnetic field lines inside a magnetic island. At the same time, the current carried by the energetic electrons accelerated in the vicinity of the X lines forms another ring at the edge of the magnetic island. Such a dual-ring current system enhances the out-of-plane magnetic field inside the magnetic island with a dip in the center of the magnetic island. In an asymmetric current sheet, when there is no guide field, electrons flow toward the X lines along the separatrices from the side with a higher density and are then directed away from the X lines along the separatrices to the side with a lower density. The formed current results in the enhancement of the out-of-plane magnetic field at one end of the magnetic island and the attenuation at the other end. With the increase of the guide field, the structures of both the current system and the out-of-plane magnetic field are distorted.

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Role of electron physics in the development of turbulent magnetic reconnection in collisionless plasmas

Cited by 541 publications

References 33 publications

Review on Current Sheets in CME Development: Theories and Observations

Review on Current Sheets in CME Development: Theories and Observations

Three-dimensional magnetic reconnection and its application to solar flares

The effect of a guide field on the structures of magnetic islands formed during multiple X line reconnections: Two‐dimensional particle‐in‐cell simulations

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