Numerical simulation of electron magnetohydrodynamics with Landau-quantized electrons in magnetar crusts

In magnetar crusts, magnetic fields are sufficiently strong to confine electrons into a small to moderate number of quantized Landau levels. This can have a dramatic effect on the crust's thermodynamic properties, generating field-dependent de Haas-van Alphen oscillations. We previously argued...

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Bibliographic Details
Published in:arXiv.org 2024-11
Main Authors: Rau, Peter B, Wasserman, Ira
Format: Article
Language:English
Subjects:
Crusts
De Haas-Van Alphen effect
Dissipation factor
Electrons
Energy spectra
Magnetars
Magnetic field configurations
Magnetic fields
Magnetic permeability
Magnetic properties
Magnetohydrodynamics
Neutron stars
Ohmic dissipation
Oscillations
Stellar models
Temperature dependence
Thermal evolution
Thermodynamic properties
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Summary:In magnetar crusts, magnetic fields are sufficiently strong to confine electrons into a small to moderate number of quantized Landau levels. This can have a dramatic effect on the crust's thermodynamic properties, generating field-dependent de Haas-van Alphen oscillations. We previously argued that the large amplitude oscillations of the magnetic susceptibility could enhance the Ohmic dissipation of the magnetic field by continuously generating small-scale, rapidly dissipating field features. This could be important to magnetar field evolution and contribute to their observed higher temperatures. To study this, we performed quasi-3D numerical simulations of electron MHD in a representative volume of neutron star crust matter, for the first time including the magnetization and magnetic susceptibility resulting from Landau quantization. We find that the potential enhancement in the Ohmic dissipation rate due to this effect can be a factor \(\sim 3\) for temperatures of order \(10^8\) K and \(\sim 4.5\) for temperatures of order \(5\times 10^7\) K, depending on the magnetic field configuration. The nonlinear Hall term is crucial to this amplification: without it the magnetic field decay is only enhanced by a factor \(\lesssim 2\) even at \(5\times 10^7\) K. These effects generate a high wave number plateau in the magnetic energy spectrum associated with the small-scale de Haas--van Alphen oscillations. Our results suggest that this mechanism could help explain the magnetar heating problem, though due to the effect's temperature-dependence, full magneto-thermal evolution simulations in a realistic stellar model are needed to judge whether it is viable explanation.
ISSN:2331-8422