Ion heating and magnetic flux pile-up in a magnetic reconnection experiment with super-Alfvénic plasma inflows

Suttle, L.; Hare, Jack; Lebedev, S. V.; Ciardi, A.; Loureiro, Nuno; Burdiak, G.; Chittenden, J. P.; Clayson, Thomas; Halliday, J. W. D.; Niasse, N.; Russell, D. R.; Vidal, François; Tubman, Eleanor; Lane, Theodore; Robinson, T.; Smith, R. A.; Stuart, Nicholas

doi:10.1063/1.5023664

Cited by 15 publications

(42 citation statements)

References 53 publications

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“…The field reconnection effects may play some role in this as the rippling is more pronounced on the anode side of the layer, where the electron current must be stronger, as they are accelerated by the reconnection electric field in y− direction. On the other hand, recent experiments specifically designed to study the reconnection layer in colliding flows do not show noticeable rippling of the reconnection layer [19].…”

Section: Verification and Discussion Of The Solutionsmentioning

confidence: 84%

Lower-hybrid drift instability and macroscopic flow of colliding magnetized plasmas

Malkov

Sotnikov

2018

Physics of Plasmas

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Microscopic instability and macroscopic flow pattern resulting from colliding plasmas are studied analytically in support of laboratory experiments. The plasma flows are assumed to stream radially from two separate centers. In a quasi-planar (2D) geometry, they may arise from an Ohmic explosion of two parallel wires, but similar configurations emerge from other outflows, e.g., colliding winds in binary star systems. One objective of this paper is to characterize the flow instabilities developing near the flow stagnation line. An exact solution for the Buneman-type dispersion equation is obtained without conventional simplifications. The unstable wave characteristics are key to anomalous resistivity that determines the reconnection rate of opposite magnetic fields transported with each flow toward the stagnation zone. The second objective of the paper is to calculate the stream function of the plasma shocked upon collision. We addressed this task by mapping the flow region to a hodograph plane and solving a Dirichlet problem for the stream function. By providing the instability growth rate, responsible for anomalous transport coefficients, and the overall flow configuration, these studies lay the ground for the next step. From there, we will examine the field reconnection scenarios and emerging mesoscopic structures, such as radial striata observed in the experiments.

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Section: Verification and Discussion Of The Solutionsmentioning

confidence: 84%

Lower-hybrid drift instability and macroscopic flow of colliding magnetized plasmas

Malkov

Sotnikov

2018

Physics of Plasmas

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“…This is ideal for the accompanying laser probing diagnostics [22], as they make path integrated measurements through the plasma, which can easily be interpreted to understand the structure of the interaction and extract the plasma parameters of interest. In demonstration of this figures 2(b) and 2(c) show interferograms of the colliding plasma flows between two aluminium wire arrays [30,32]. Localized measurements of the flow velocities and electron and ion temperatures come from the optical Thomson scattering diagnostic [22].…”

Section: Magnetic Reconnection In Counter-streaming Magnetized Plasmamentioning

confidence: 96%

“…Magnetic reconnection is a complex and multifaceted process which is an active topic of research across space, astrophysics and plasma physics [28,29]. One of the most notable applications of the inverse wire array setup therefore has been to create a platform for studying this process in the laboratory [25,[30][31][32][33]. In these experiments two identical inverse wire arrays are fielded side-by-side on the MAGPIE generator, connected in parallel and in the same polarity to each receive a 50% share of the current supply.…”

Section: Magnetic Reconnection In Counter-streaming Magnetized Plasmamentioning

confidence: 99%

“…The heating is therefore expected to draw directly from the released magnetic energy in the reconnection current sheet. This however would require a resistivity approximately 10× greater than the Spitzer resistivity to provide heating on a fast-enough timescale to heat the plasma before it leaves the reconnection layer [31,32]. Anomalous heating has been observed in numerous other reconnection experiments (see review of [28] and references therein), and could potentially arise from the development of instabilities in the reconnection layer.…”

Section: Magnetic Reconnection In Counter-streaming Magnetized Plasmamentioning

confidence: 99%

“…(b) Carbon wire arrays produce a layer which is unstable to the production of plasmoids. Multi-frame videos showing the dynamics of the respective layers over each experiment can be found in the references[32] and[25].…”

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confidence: 99%

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Interactions of magnetized plasma flows in pulsed-power driven experiments

Suttle

Burdiak

Cheung

et al. 2019

Plasma Phys. Control. Fusion

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A supersonic flow of magnetized plasma is produced by the application of a 1 MA-peak, 500 ns current pulse to a cylindrical arrangement of parallel wires, known as an inverse wire array. The plasma flow is produced by the × acceleration of the ablated wire material, and a magnetic field of several Tesla is embedded at source by the driving current. This setup has been used for a variety of experiments investigating the interactions of magnetized plasma flows. In experiments designed to investigate magnetic reconnection, the collision of counter-streaming flows, carrying oppositely directed magnetic fields, leads to the formation of a reconnection layer in which we observe ions reaching temperatures much greater than predicted by classical heating mechanisms. The breakup of this layer under the plasmoid instability is dependent on the properties of the inflowing plasma, which can be controlled by the choice of the wire array material. In other experiments, magnetized shocks were formed by placing obstacles in the path of the magnetized plasma flow. The pile-up of magnetic flux in front of a conducting obstacle produces a magnetic precursor acting on upstream electrons at the distance of the ion inertial length. This precursor subsequently develops into a steep density transition via ion-electron fluid decoupling. Obstacles which possess a strong private magnetic field affect the upstream flow over a much greater distance, providing an extended bow shock structure.In the region surrounding the obstacle the magnetic pressure holds off the flow, forming a void of plasma material, analogous to the magnetopause around planetary bodies with self-generated magnetic fields.

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Persistent mysteries of jet engines, formation, propagation, and particle acceleration: Have they been addressed experimentally?

Blackman

Lebedev

2022

New Astronomy Reviews

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Ion heating and magnetic flux pile-up in a magnetic reconnection experiment with super-Alfvénic plasma inflows

Cited by 15 publications

References 53 publications

Lower-hybrid drift instability and macroscopic flow of colliding magnetized plasmas

Lower-hybrid drift instability and macroscopic flow of colliding magnetized plasmas

Interactions of magnetized plasma flows in pulsed-power driven experiments

Persistent mysteries of jet engines, formation, propagation, and particle acceleration: Have they been addressed experimentally?

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