Magnetic field evolution in neutron stars

Reisenegger, Andreas

doi:10.1002/asna.200710848

Cited by 24 publications

(22 citation statements)

References 39 publications

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“…Hall drift and buoyant rise provide natural explanations for this as they scale with the field strength, as B and B 2 , respectively. Buoyancy of flux tubes in NSs depends mainly on the composition gradient, the difference with WDs being that not only can chemical elements diffuse into or out of a flux tube but also that the chemical elements can reach equilibrium via the neutrino‐emitting reaction n ⇔ p + e (Reisenegger 2007). The speed of the latter does not depend on the length‐scale, so fields with narrow flux tubes would evolve no faster than simpler fields if this were the dominant mechanism.…”

Section: Discussionmentioning

confidence: 99%

“…In an axisymmetric equilibrium, the buoyant-rising effect of thermal diffusion is resisted by the tension of the toroidal component. As Reisenegger (2007) points out, this is likely to be more important when the torus is buried deep inside the star, which could explain why magnetic diffusion may be more important in deeply buried fields. 5 As axisymmetric equilibrium with a flatter radial energy profile diffuses outwards, it experiences the same loss of toroidal flux as the non-axisymmetric equilibria.…”

Section: Axisymmetric Equilibriamentioning

confidence: 99%

“…In an axisymmetric equilibrium, the buoyant‐rising effect of thermal diffusion is resisted by the tension of the toroidal component. As Reisenegger (2007) points out, this is likely to be more important when the torus is buried deep inside the star, which could explain why magnetic diffusion may be more important in deeply buried fields 5…”

Section: Diffusive Evolution Of Equilibriamentioning

confidence: 99%

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On non-axisymmetric magnetic equilibria in stars

Braithwaite

2008

Monthly Notices RAS

124

159

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In previous work stable approximately axisymmetric equilibrium configurations for magnetic stars were found by numerical simulation. Here I investigate the conditions under which more complex, non-axisymmetric configurations can form. I present numerical simulations of the formation of stable equilibria from turbulent initial conditions and demonstrate the existence of non-axisymmetric equilibria consisting of twisted flux tubes lying horizontally below the surface of the star, meandering around the star in random patterns. Whether such a non-axisymmetric equilibrium or a simple axisymmetric equilibrium forms depends on the radial profile of the strength of the initial magnetic field. The results could explain observations of non-dipolar fields on stars such as the B0.2 main-sequence star tau-Sco or the pulsar 1E 1207.4-5209. The secular evolution of these equilibria due to Ohmic and buoyancy processes is also examined.Comment: 13 pages, 12 figures. Accepted by MNRA

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Section: Discussionmentioning

confidence: 99%

Section: Axisymmetric Equilibriamentioning

confidence: 99%

Section: Diffusive Evolution Of Equilibriamentioning

confidence: 99%

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On non-axisymmetric magnetic equilibria in stars

Braithwaite

2008

Monthly Notices RAS

124

159

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“…In each of these classes there is a wide distribution of magnetic field strengths, but the distribution of magnetic fluxes appears to be similar in each class, with maxima of Φ max = πR 2 B ∼ 10 27−28 G cm 2 (Reisenegger 2001; Ferrario & Wickramasinghe 2005), arguing for a fossil field whose flux is conserved along the path of stellar evolution. According to Reisenegger (2009) the magnetic fluxes have possibly been generated on or even before the main-sequence stage and then inherited by the compact remnants.…”

Section: Magnetic Field Measurementsmentioning

confidence: 99%

First detection of a magnetic field in the fast rotating runaway Oe star ζ Ophiuchi

2011

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The star ζ Ophiuchi is one of the brightest massive stars in the northern hemisphere and was intensively studied in various wavelength domains. The currently available observational material suggests that certain observed phenomena are related to the presence of a magnetic field. We acquired spectropolarimetric observations of ζ Oph with FORS 1 mounted on the 8-m Kueyen telescope of the VLT to investigate if a magnetic field is indeed present in this star. Using all available absorption lines, we detect a mean longitudinal magnetic field Bz all = 141 ± 45 G, confirming the magnetic nature of this star. We review the X-ray properties of ζ Oph with the aim to understand whether the X-ray emission of ζ Oph is dominated by magnetic or by wind instability processes.

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“…However the origin of the magnetic field in the neutron stars is not fully understood, so far. Nevertheless in the literature one may find various hypotheses explaining the formation of the magnetic field 1,2,3,4,5,6,7 . The simplest hypothesis to explain the presence of the strong fields observed in neutron stars is the conservation of the magnetic flux already present in the progenitor stars during the gravitational collapse.…”

Section: Introductionmentioning

confidence: 99%

On Magnetic Fields in Rotating Nuclear Matter Cores of Stellar Dimensions

Boshkayev

Rotondo

Ruffini

2012

Int. J. Mod. Phys. Conf. Ser.

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We consider a degenerate globally neutral system of stellar dimensions consisting of Nn neutrons, Np protons and Ne electrons in beta equilibrium. Such a system at nuclear density having mass numbers A ≈ 10 57 can exhibit a charge distribution different from zero. We present the analysis in the framework of classical electrodynamics to investigate the magnetic field induced by this charge distribution when the system is allowed to rotate as a whole rigid body with constant angular velocity around the axis of symmetry.

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Magnetic field evolution in neutron stars

Cited by 24 publications

References 39 publications

On non-axisymmetric magnetic equilibria in stars

On non-axisymmetric magnetic equilibria in stars

First detection of a magnetic field in the fast rotating runaway Oe star ζ Ophiuchi

On Magnetic Fields in Rotating Nuclear Matter Cores of Stellar Dimensions

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