Three dimensional simulation of the magnetic stress in a neutron star crust

Three dimensional simulation of the magnetic stress in a neutron star crust

We present the first fully self-consistent three dimensional model of a neutron star's magnetic field, generated by electric currents in the star's crust via the Hall effect. We find that the global-scale field converges to a dipolar Hall-attractor state, as seen in recent axisymmetric mod...

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Veröffentlicht in:Physical review letters 2015-05, Vol.114 (19), p.191101-191101, Article 191101
Hauptverfasser: Wood, T S, Hollerbach, R
Format: Artikel
Sprache:eng
Schlagworte:
Crusts
Electric current
Equatorial regions
Magnetic fields
Mathematical models
Neutron stars
Small scale
Stresses
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Zusammenfassung:We present the first fully self-consistent three dimensional model of a neutron star's magnetic field, generated by electric currents in the star's crust via the Hall effect. We find that the global-scale field converges to a dipolar Hall-attractor state, as seen in recent axisymmetric models, but that small-scale features in the magnetic field survive even on much longer time scales. These small-scale features propagate toward the dipole equator, where the crustal electric currents organize themselves into a strong equatorial jet. By calculating the distribution of magnetic stresses in the crust, we predict that neutron stars with fields stronger than 10^{14} G can still be subject to starquakes more than 10^{5} yr after their formation.
ISSN:0031-9007
1079-7114
DOI:10.1103/physrevlett.114.191101