Saturn's Plasma Density Depletions Along Magnetic Field Lines Connected to the Main Rings

Abstract. A double discontinuity is a compound structure composed of a slow shock layer and an adjoining rotational discontinuity layer on the postshock side. We use high-resolution data from Geotail and Wind spacecraft to examine the interior structure within the finite thickness of the discontinuity at the plasma sheet-lobe boundary and found that recognizable MHD structures at the boundary can be stand-alone slow shocks or double discontinuities. The plasma density increases significantly and the magnetic field intensity decreases significantly across the interior of the slow shock layer. Through the rotational layer, the magnetic field rotates about the normal direction of the shock surface, as the plasma density and the magnetic field intensity remain nearly unchanged. The rotational angle can vary over a wide range. We notice that the observations of double discontinuities are no less frequent than the observations of stand-alone slow shocks. Identification of slow shocks and double discontinuities infers that plasma and magnetic field lines continuously move across the boundary surface from the lobe into the plasma sheet, and there is a conversion of magnetic field energy into plasma thermal energy through the slow shock layer. The double discontinuities also allows for a rapid rotation of the postshock magnetic field lines immediately behind the shock layer to accommodate the environment of the MHD flow in the plasma sheet region.Key words. Magnetospheric physics (plasma sheet) Space plasma physics (discontinuities; shock waves)

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Interchange instability of the plasma disk in Jupiter's middle magnetosphere and its relation to the radial plasma density distribution

Annales Geophysicae ◽

10.5194/angeo-24-2043-2006 ◽

2006 ◽

Vol 24 (7) ◽

pp. 2043-2055 ◽

Cited By ~ 5

Author(s):

P. A. Bespalov ◽

S. S. Davydenko ◽

S. W. H. Cowley ◽

J. D. Nichols

Keyword(s):

Magnetic Field ◽

Plasma Density ◽

Density Profile ◽

High Latitude ◽

Small Scale ◽

Radial Density ◽

Initial Examination ◽

Flute Instability ◽

Smoothing Effects ◽

Field Lines

Abstract. We analyse the interchange or flute instability of the equatorial plasma disk in Jupiter's middle magnetosphere. Particular attention is paid to wave coupling between the dense plasma in the equatorial disk and the more rarefied plasma at higher latitudes, and between the latter plasma and the conducting ionosphere at the feet of the field lines. It is assumed that the flute perturbations are of small spatial scale in the azimuthal direction, such that a local Cartesian approximation may be employed, in which the effect of the centrifugal acceleration associated with plasma rotation is represented by an "external" force in the "radial" direction, perpendicular to the plasma flow. For such small-scale perturbations the ionosphere can also be treated as a perfect electrical conductor, and the condition is determined under which this approximation holds. We then examine the condition under which flute perturbations are at the threshold of instability, and use this to determine the corresponding limiting radial density gradient within the plasma disk. We find that when the density of the high-latitude plasma is sufficiently low compared with that of the disk, such that coupling to the ionosphere is not important, the limiting radial density profile within the disk follows that of the equatorial magnetic field strength as expected. However, as the density of the high-latitude plasma increases toward that of the equatorial disk, the limiting density profile in the disk falls increasingly steeply compared with that of the magnetic field, due to the increased stabilising effect of the ionospheric interaction. An initial examination of Galileo plasma density and magnetic field profiles, specifically for orbit G08, indicates that the latter effect is indeed operative inside radial distances of ~20 RJ. At larger distances, however, additional density smoothing effects appear to be important.

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Experimental studies of toroidal correlations of plasma density fluctuations along the magnetic field lines in the T-10 tokamak and first results of numerical modeling

Journal of Physics Conference Series ◽

10.1088/1742-6596/907/1/012001 ◽

2017 ◽

Vol 907 ◽

pp. 012001 ◽

Cited By ~ 1

Author(s):

M A Buldakov ◽

V A Vershkov ◽

M Yu Isaev ◽

D A Shelukhin

Keyword(s):

Magnetic Field ◽

Numerical Modeling ◽

Plasma Density ◽

Experimental Studies ◽

Density Fluctuations ◽

First Results ◽

Field Lines ◽

The Magnetic Field

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Stochastic magnetic field lines diffusion in a toroidal configuration (Tokamak)

The European Physical Journal Applied Physics ◽

10.1051/epjap:2000181 ◽

2000 ◽

Vol 12 (2) ◽

pp. 145-153 ◽

Cited By ~ 1

Author(s):

R. Tabet ◽

H. Imrane ◽

D. Saifaoui ◽

A. Dezairi ◽

F. Miskane

Keyword(s):

Magnetic Field ◽

Field Lines ◽

Stochastic Magnetic Field

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Exact nonlinear wave solutions of the incompressible magnetohydrodynamic equations in a sheared magnetic field

Journal of Plasma Physics ◽

10.1017/s0022377800014987 ◽

1990 ◽

Vol 44 (1) ◽

pp. 25-32 ◽

Cited By ~ 11

Author(s):

Hiromitsu Hamabata

Keyword(s):

Magnetic Field ◽

Incompressible Fluid ◽

Large Amplitude ◽

Uniform Magnetic Field ◽

Magnetohydrodynamic Equations ◽

Wave Solutions ◽

Field Lines ◽

Incompressible Magnetohydrodynamic Equations ◽

Physical Quantities ◽

Nonlinear Wave Solutions

Exact wave solutions of the nonlinear jnagnetohydrodynamic equations for a highly conducting incompressible fluid are obtained for the cases where the physical quantities are independent of one Cartesian co-ordina.te and for where they vary three-dimensionally but both the streamlines and magnetic field lines lie in parallel planes. It is shown that there is a class of exact wave solutions with large amplitude propagating in a straight but non-uniform magnetic field with constant or non-uniform velocity.

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Magnetic nulls in interacting dipolar fields

Journal of Plasma Physics ◽

10.1017/s0022377821000210 ◽

2021 ◽

Vol 87 (2) ◽

Author(s):

Todd Elder ◽

Allen H. Boozer

Keyword(s):

Magnetic Field ◽

Current Density ◽

Magnetic Flux Tube ◽

Electron Inertia ◽

Characteristic Spatial Scale ◽

Field Lines ◽

Dipolar Fields ◽

Time Required ◽

Magnetic Null ◽

The Magnetic Field

The prominence of nulls in reconnection theory is due to the expected singular current density and the indeterminacy of field lines at a magnetic null. Electron inertia changes the implications of both features. Magnetic field lines are distinguishable only when their distance of closest approach exceeds a distance $\varDelta _d$ . Electron inertia ensures $\varDelta _d\gtrsim c/\omega _{pe}$ . The lines that lie within a magnetic flux tube of radius $\varDelta _d$ at the place where the field strength $B$ is strongest are fundamentally indistinguishable. If the tube, somewhere along its length, encloses a point where $B=0$ vanishes, then distinguishable lines come no closer to the null than $\approx (a^2c/\omega _{pe})^{1/3}$ , where $a$ is a characteristic spatial scale of the magnetic field. The behaviour of the magnetic field lines in the presence of nulls is studied for a dipole embedded in a spatially constant magnetic field. In addition to the implications of distinguishability, a constraint on the current density at a null is obtained, and the time required for thin current sheets to arise is derived.

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Unveiling stickiness regions of magnetic field lines in tokamaks

Indian Journal of Physics ◽

10.1007/s12648-021-02174-2 ◽

2021 ◽

Author(s):

A. R. Sohrabi ◽

S. M. Jazayeri

Keyword(s):

Magnetic Field ◽

Field Lines

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Magnetic Field Spectroheliograms from the San Fernando Observatory

Symposium - International Astronomical Union ◽

10.1017/s0074180900022774 ◽

1971 ◽

Vol 43 ◽

pp. 329-339 ◽

Cited By ~ 30

Author(s):

Dale Vrabec

Keyword(s):

Magnetic Field ◽

Magnetic Fields ◽

Spiral Structure ◽

Longitudinal Component ◽

Solar Telescope ◽

Solar Magnetic Fields ◽

San Fernando ◽

Field Lines ◽

The Magnetic Field ◽

Field Network

Zeeman spectroheliograms of photospheric magnetic fields (longitudinal component) in the CaI 6102.7 Å line are being obtained with the new 61-cm vacuum solar telescope and spectroheliograph, using the Leighton technique. The structure of the magnetic field network appears identical to the bright photospheric network visible in the cores of many Fraunhofer lines and in CN spectroheliograms, with the exception that polarities are distinguished. This supports the evolving concept that solar magnetic fields outside of sunspots exist in small concentrations of essentially vertically oriented field, roughly clumped to form a network imbedded in the otherwise field-free photosphere. A timelapse spectroheliogram movie sequence spanning 6 hr revealed changes in the magnetic fields, including a systematic outward streaming of small magnetic knots of both polarities within annular areas surrounding several sunspots. The photospheric magnetic fields and a series of filtergrams taken at various wavelengths in the Hα profile starting in the far wing are intercompared in an effort to demonstrate that the dark strands of arch filament systems (AFS) and fibrils map magnetic field lines in the chromosphere. An example of an active region in which the magnetic fields assume a distinct spiral structure is presented.

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Efficiency of thermal conduction in a magnetized circumgalactic medium

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab110 ◽

2021 ◽

Vol 502 (1) ◽

pp. 1263-1278

Author(s):

Richard Kooij ◽

Asger Grønnow ◽

Filippo Fraternali

Keyword(s):

Magnetic Field ◽

Thermal Conduction ◽

Large Temperature ◽

Gas Condensation ◽

Circumgalactic Medium ◽

Field Lines ◽

Gas Accretion ◽

Cloud Evolution ◽

The Magnetic Field ◽

Cold Gas

ABSTRACT The large temperature difference between cold gas clouds around galaxies and the hot haloes that they are moving through suggests that thermal conduction could play an important role in the circumgalactic medium. However, thermal conduction in the presence of a magnetic field is highly anisotropic, being strongly suppressed in the direction perpendicular to the magnetic field lines. This is commonly modelled by using a simple prescription that assumes that thermal conduction is isotropic at a certain efficiency f < 1, but its precise value is largely unconstrained. We investigate the efficiency of thermal conduction by comparing the evolution of 3D hydrodynamical (HD) simulations of cold clouds moving through a hot medium, using artificially suppressed isotropic thermal conduction (with f), against 3D magnetohydrodynamical (MHD) simulations with (true) anisotropic thermal conduction. Our main diagnostic is the time evolution of the amount of cold gas in conditions representative of the lower (close to the disc) circumgalactic medium of a Milky-Way-like galaxy. We find that in almost every HD and MHD run, the amount of cold gas increases with time, indicating that hot gas condensation is an important phenomenon that can contribute to gas accretion on to galaxies. For the most realistic orientations of the magnetic field with respect to the cloud motion we find that f is in the range 0.03–0.15. Thermal conduction is thus always highly suppressed, but its effect on the cloud evolution is generally not negligible.

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Study of relativistic magnetized outflows with relativistic equation of state

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stz2101 ◽

2019 ◽

Vol 488 (4) ◽

pp. 5713-5727

Author(s):

Kuldeep Singh ◽

Indranil Chattopadhyay

Keyword(s):

Magnetic Field ◽

Angular Momentum ◽

Equation Of State ◽

Polar Angle ◽

Relativistic Equation ◽

Azimuthal Velocity ◽

Astrophysical Jets ◽

Composition Parameter ◽

Field Lines ◽

Flow Experiences

ABSTRACT We study relativistic magnetized outflows using relativistic equation of state having variable adiabatic index (Γ) and composition parameter (ξ). We study the outflow in special relativistic magnetohydrodynamic regime, from sub-Alfvénic to super-fast domain. We showed that, after the solution crosses the fast point, magnetic field collimates the flow and may form a collimation-shock due to magnetic field pinching/squeezing. Such fast, collimated outflows may be considered as astrophysical jets. Depending on parameters, the terminal Lorentz factors of an electron–proton outflow can comfortably exceed few tens. We showed that due to the transfer of angular momentum from the field to the matter, the azimuthal velocity of the outflow may flip sign. We also study the effect of composition (ξ) on such magnetized outflows. We showed that relativistic outflows are affected by the location of the Alfvén point, the polar angle at the Alfvén point and also the angle subtended by the field lines with the equatorial plane, but also on the composition of the flow. The pair dominated flow experiences impressive acceleration and is hotter than electron–proton flow.

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