Hall currents in a current sheet: Structure and dynamics

Frank, A. G.; Bugrov, Sergey; Markov, V. S.

doi:10.1063/1.2972158

Cited by 60 publications

(39 citation statements)

References 21 publications

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“…More recently, it was established that the magnetic field of such a current sheet frequently takes on a 3D configuration due to generation of Hall currents [5][6][7][8][9][10][11][12][13][14][15]. Compared to the 2D case, the magnetic field structure becomes more complicated when the current sheet is produced in the initial 3D magnetic configuration, in the presence of the out-of-plane magnetic field component (guide field) aligned with the X line.…”

mentioning

confidence: 99%

“…The regions of the excess guide field prove to be precisely the regions, where the main current aligned with the X line is localized. It should be pointed out that in this experiment, the guide field produced by the Hall currents is negligibly small because of appropriate choosing the instants of time and space positions for measurements (for details, see [15,28]). It is evident that an enhancement of the guide field is available because of appearance of the in-plane plasma currents.…”

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confidence: 99%

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Enhancement of the guide field during the current sheet formation in the three-dimensional magnetic configuration with an X line

2009

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confidence: 99%

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confidence: 99%

Enhancement of the guide field during the current sheet formation in the three-dimensional magnetic configuration with an X line

2009

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“…More recently, however, experiments that are in an MHD regime (i.e. d i and ρ i much smaller than the device size) have been able to find these two-fluid effects within their current sheets [24][25][26]. Finally, these effects have also been found by spacecraft flying through reconnecting current sheets in the earth's magnetosphere [27].…”

Section: Magnetic Reconnectionmentioning

confidence: 91%

Experimental Study of Current-Driven Turbulence During Magnetic Reconnection

Porkoláb¹,

Egedal-Pedersen²,

Fox³

2010

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Magnetic reconnection is an important process in magnetized plasmas ranging from the laboratory to astrophysical scales. It enables the release of magnetic energy believed to power solar flares and magnetospheric substorms. Reconnection also controls the evolution of the topology of the magnetic field, enabling deleterious instabilities, such as the sawtooth instability in fusion experiments, to transport plasma across the experiment's minor radius. Notably, simple estimates of the finite reconnection rate due to classical resistivity fail to explain the fast and explosive nature of reconnection observed in these systems. A major goal of reconnection research is to determine which mechanisms enable "fast" reconnection to occur.This thesis studied the fluctuations arising in the plasma during magnetic reconnection experiments on the Versatile Toroidal Facility (VTF), with a primary goal of testing whether "anomalous resistivity" due to micro-instabilities can speed the reconnection process. Fluctuations were studied using impedance-matched, high-bandwidth Langmuir probes. Strong, broadband fluctuations, with frequencies extending from near the lower-hybrid frequency [f LH = (f ce f ci ) 1/2 ] to the electron cyclotron frequency f ce were found to arise during the reconnection events. Based on frequency and wavelength measurements, lower-hybrid waves and Trivelpiece-Gould waves were identified. The lower-hybrid waves appear to be driven by strong perpendicular drifts or gradients which arise due to the reconnection events; an appealing possibility is strong temperature gradients. The Trivelpiece-Gould modes were found to result from kinetic, bump-on-tail instability of a runaway electron population energized by the reconnection events. Nonlinear, spiky turbulence was also observed, and attributed to the creation of "electron phase-space holes," a class of nonlinear solitary wave known to evolve from a strong beam-on-tail instability.Overall, these instabilities were found to be a consequence of reconnection, specifically the strong energization of electrons, leading to steep gradients in both coordinate-and velocity-space. However, it was not established that these modes had a strong feedback on the reconnection process: fluctuation power varied strongly between discharges and was observed to systematically trail the reconnection events. Finally, crude estimates (using quasi-linear theory) of the anomalous resistivity due to these modes did not appear large enough to substantially impact the reconnection process.

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“…The CS characteristic dimensions are: length Δz, width 2δx ≈ (8-12) cm, and thickness 2δy ≈ (1.5-3.5) cm. Plasma current concentration in the CS modifies the initial configuration (2.1): the tangential component B x increases significantly, while the normal component (Frank & Bogdanov 2001;Frank et al 2008Frank et al , 2009). The CS formation results also in effective plasma compression into the sheet, so that the electron density in the CS mid-plane increases up to (1-3)·10 16 cm −3 , i.e., it is 5-15 times the initial density (Bogdanov et al 2002;Frank et al 2005).…”

Section: Experimental Device Cs-3d and Current Sheet Formationmentioning

confidence: 99%

“…The pressure gradient impedes compression and the CS formation brings about the establishment of transverse equilibrium. The pressure gradient is negligible along the CS surface (x-axis), whereas the Ampere forces are of crucial importance for the Hall current excitation (Frank et al 2008) and the generation of plasma jets (Kyrie et al 2010). The Ampere force [j × B] x along the CS width is determined by current j z and normal component B y , which is usually nonzero in the metastable CS (Fig.…”

Section: Generation Of Plasma Jets In Current Sheetsmentioning

confidence: 99%