Dependence of volumes of magnetic flux tubes on plasma pressure and disturbance in the magnetic field in the axially symmetric case

The magnetic field of the Sun is mainly concentrated into intense magnetic flux tubes having field strengths of the order of 1 kG. In this paper an overview is given of the thermal and magnetic properties of these flux tubes, which are known to exhibit a large range in size, from the smallest magnetic elements to sunspots. Differences and similarities between the largest and smallest features are stressed. Some thoughts are also presented on how the properties of magnetic flux tubes are expected to scale from the solar case to that of solar-like stars. For example, it is pointed out that on giants and supergiants turbulent pressure may dominate over gas pressure as the main confining agent of the magnetic field. Arguments are also presented in favour of a highly complex magnetic geometry on very active stars. Thus the very large starspots seen in Doppler images probably are conglomerates of smaller (but possibly still sizable) spots.

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Effects of MHD slow shocks propagating along magnetic flux tubes in a dipole magnetic field

Nonlinear Processes in Geophysics ◽

10.5194/npg-9-163-2002 ◽

2002 ◽

Vol 9 (2) ◽

pp. 163-172 ◽

Cited By ~ 6

Author(s):

N. V. Erkaev ◽

V. A. Shaidurov ◽

V. S. Semenov ◽

H. K. Biernat

Keyword(s):

Magnetic Field ◽

Magnetic Flux ◽

Flux Tube ◽

Plasma Pressure ◽

Mhd Waves ◽

Magnetic Flux Tube ◽

Flux Tubes ◽

Dipole Magnetic Field ◽

Pressure Pulses ◽

Magnetic Flux Tubes

Abstract. Variations of the plasma pressure in a magnetic flux tube can produce MHD waves evolving into shocks. In the case of a low plasma beta, plasma pressure pulses in the magnetic flux tube generate MHD slow shocks propagating along the tube. For converging magnetic field lines, such as in a dipole magnetic field, the cross section of the magnetic flux tube decreases enormously with increasing magnetic field strength. In such a case, the propagation of MHD waves along magnetic flux tubes is rather different from that in the case of uniform magnetic fields. In this paper, the propagation of MHD slow shocks is studied numerically using the ideal MHD equations in an approximation suitable for a thin magnetic flux tube with a low plasma beta. The results obtained in the numerical study show that the jumps in the plasma parameters at the MHD slow shock increase greatly while the shock is propagating in the narrowing magnetic flux tube. The results are applied to the case of the interaction between Jupiter and its satellite Io, the latter being considered as a source of plasma pressure pulses.

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Investigation of Spatially Unresolved Magnetic Field Outside Sunspots Using Hinode/SOT Observations

Proceedings of the International Astronomical Union ◽

10.1017/s1743921316013016 ◽

2016 ◽

Vol 12 (S325) ◽

pp. 59-62

Author(s):

Olga Botygina ◽

Mykola Gordovskyy ◽

Vsevolod Lozitsky

Keyword(s):

Magnetic Field ◽

Magnetic Fields ◽

Magnetic Flux ◽

Zeeman Effect ◽

Active Regions ◽

Line Ratio ◽

Optical Telescope ◽

Flux Tubes ◽

Magnetic Flux Tubes ◽

The Magnetic Field

AbstractThe structure of photospheric magnetic fields outside sunspots is investigated in three active regions using Hinode/Solar Optical Telescope(SOT) observations. We analyze Zeeman effect in FeI 6301.5 and FeI 6302.5 lines and determine the observed magnetic field value Beff for each of them. We find that the line ratio Beff(6301)/Beff(6302) is close to 1.3 in the range Beff < 0.2 kG, and close to 1.0 for 0.8 kG < Beff < 1.2 kG. We find that the observed magnetic field is formed by flux tubes with the magnetic field strengths 1.3 − 2.3 kG even in places with weak observed magnetic field fluxes. We also estimate the diameters of smallest magnetic flux tubes to be 15 − 20 km.

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Energy Storage and Instability in Magnetic Flux Tubes

Symposium - International Astronomical Union ◽

10.1017/s0074180900067735 ◽

1980 ◽

Vol 91 ◽

pp. 291-294

Author(s):

Takashi Sakurai

Keyword(s):

Magnetic Field ◽

Energy Storage ◽

Magnetic Flux ◽

Solar Corona ◽

Free Field ◽

Flux Tubes ◽

Magnetic Flux Tubes ◽

Image Position ◽

The Magnetic Field ◽

Force Free Field

Now it is known that the solar corona consists of many loops which are believed to represent the structure of the magnetic field. Since the plasma is very tenuous in the corona, the equilibrium of the magnetic field is approximated by the force-free field:

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Magnetic Flux Concentration by Siphon Flows in Isolated Magnetic Flux Tubes

Symposium - International Astronomical Union ◽

10.1017/s0074180900044211 ◽

1990 ◽

Vol 138 ◽

pp. 263-266

Author(s):

John H. Thomas ◽

Benjamin Montesinos

Keyword(s):

Magnetic Field ◽

Magnetic Flux ◽

Magnetic Polarity ◽

Small Scale ◽

Solar Photosphere ◽

Flux Tubes ◽

Magnetic Structures ◽

Flux Concentration ◽

Magnetic Flux Tubes ◽

The Magnetic Field

Siphon flows along arched, isolated magnetic flux tubes, connecting photospheric footpoints of opposite magnetic polarity, cause a significant increase in the magnetic field strength of the flux tube due to the decreased internal gas pressure associated with the flow (the Bernoulli effect). These siphon flows offer a possible mechanism for producing intense, inclined, small-scale magnetic structures in the solar photosphere.

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Study of helicity properties of peculiar active regions

Proceedings of the International Astronomical Union ◽

10.1017/s1743921309992493 ◽

2009 ◽

Vol 5 (S264) ◽

pp. 102-104 ◽

Cited By ~ 1

Author(s):

M. C. López Fuentes ◽

C. H. Mandrini ◽

P. Démoulin

Keyword(s):

Magnetic Field ◽

Magnetic Flux ◽

Active Regions ◽

Solar Interior ◽

Magnetic Helicity ◽

Flux Tubes ◽

Origin And Evolution ◽

Magnetic Structures ◽

Magnetic Flux Tubes ◽

The Magnetic Field

AbstractPeculiar solar active regions (ARs), such as δ-islands and other high tilt bipoles, are commonly associated with the emergence of severely deformed magnetic flux tubes. Therefore, the study of these ARs provides valuable information on the origin and evolution of magnetic structures in the solar interior. Here, we infer the magnetic helicity properties of the flux tubes associated to a set of peculiar ARs by studying the evolution of photospheric magnetograms (SOHO/MDI) and coronal observations (SOHO/EIT and TRACE) in combination with force-free models of the magnetic field. We discuss how our results relate to different models of the evolution of emerging magnetic flux tubes.

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Ion velocity distributions within the LLBL and their possible implication to multiple reconnections

Annales Geophysicae ◽

10.5194/angeo-22-213-2004 ◽

2004 ◽

Vol 22 (1) ◽

pp. 213-236 ◽

Cited By ~ 4

Author(s):

O. L. Vaisberg ◽

L. A. Avanov ◽

T. E. Moore ◽

V. N. Smirnov

Keyword(s):

Magnetic Field ◽

Magnetic Flux ◽

Flux Tube ◽

Magnetic Flux Tube ◽

Flux Tubes ◽

Different Types ◽

Subsolar Point ◽

Magnetic Flux Tubes ◽

Ion Velocity ◽

Field Lines

Abstract. We analyze two LLBL crossings made by the Interball-Tail satellite under a southward or variable magnetosheath magnetic field: one crossing on the flank of the magnetosphere, and another one closer to the subsolar point. Three different types of ion velocity distributions within the LLBL are observed: (a) D-shaped distributions, (b) ion velocity distributions consisting of two counter-streaming components of magnetosheath-type, and (c) distributions with three components, one of which has nearly zero parallel velocity and two counter-streaming components. Only the (a) type fits to the single magnetic flux tube formed by reconnection between the magnetospheric and magnetosheath magnetic fields. We argue that two counter-streaming magnetosheath-like ion components observed by Interball within the LLBL cannot be explained by the reflection of the ions from the magnetic mirror deeper within the magnetosphere. Types (b) and (c) ion velocity distributions would form within spiral magnetic flux tubes consisting of a mixture of alternating segments originating from the magnetosheath and from magnetospheric plasma. The shapes of ion velocity distributions and their evolution with decreasing number density in the LLBL indicate that a significant part of the LLBL is located on magnetic field lines of long spiral flux tube islands at the magnetopause, as has been proposed and found to occur in magnetopause simulations. We consider these observations as evidence for multiple reconnection Χ-lines between magnetosheath and magnetospheric flux tubes. Key words. Magnetospheric physics (magnetopause, cusp and boundary layers; solar wind-magnetosphere interactions)

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The Small-Scale Photospheric Magnetic Field as an Indicator of the Dynamo

International Astronomical Union Colloquium ◽

10.1017/s0252921100028979 ◽

1993 ◽

Vol 141 ◽

pp. 143-146

Author(s):

K. Petrovay ◽

G. Szakály

Keyword(s):

Magnetic Field ◽

Magnetic Fields ◽

Magnetic Flux ◽

Observational Data ◽

Convective Zone ◽

Small Scale ◽

Dynamo Theory ◽

Flux Tubes ◽

Magnetic Flux Tubes ◽

Surface Fields

AbstractThe presently widely accepted view that the solar dynamo operates near the base of the convective zone makes it difficult to relate the magnetic fields observed in the solar atmosphere to the fields in the dynamo layer. The large amount of observational data concerning photospheric magnetic fields could in principle be used to impose constraints on dynamo theory, but in order to infer these constraints the above mentioned “missing link” between the dynamo and surface fields should be found. This paper proposes such a link by modeling the passive vertical transport of thin magnetic flux tubes through the convective zone.

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Rising magnetic flux tubes as a source of IR-variability of the accretion disks of young stars

Proceedings of the International Astronomical Union ◽

10.1017/s1743921319001431 ◽

2018 ◽

Vol 14 (S345) ◽

pp. 295-296

Author(s):

Sergey A. Khaibrakhmanov ◽

Alexander E. Dudorov ◽

Andrey M. Sobolev

Keyword(s):

Magnetic Field ◽

Magnetic Flux ◽

Accretion Disks ◽

Young Stars ◽

Flux Tubes ◽

Magnetic Flux Tubes

AbstractWe investigate dynamics of slender magnetic flux tubes (MFT) in the accretion disks of young stars. Simulations show that MFT rise from the disk and can accelerate to 20-30 km/s causing periodic outflows. Magnetic field of the disk counteracts the buoyancy, and the MFT oscillate near the disk’s surface with periods of 10-100 days. We demonstrate that rising and oscillating MFT can cause the IR-variability of the accretion disks of young stars.

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