English

Toward a Realistic Pulsar Magnetosphere

Solar and Stellar Astrophysics 2015-05-30 v2 Plasma Physics

Abstract

We present the magnetic and electric field structures as well as the currents and charge densities of pulsar magnetospheres which do not obey the ideal condition, EB=0{\bf E \cdot B =0}. Since the acceleration of particles and the production of radiation requires the presence of an electric field component parallel to the magnetic field, E{\bf E}_\parallel, the structure of non-Ideal pulsar magnetospheres is intimately related to the production of pulsar radiation. Therefore, knowledge of the structure of non-Ideal pulsar magnetospheres is important because their comparison (including models for the production of radiation) with observations will delineate the physics and the parameters underlying the pulsar radiation problem. We implement a variety of prescriptions that support nonzero values for E{\bf E}_\parallel and explore their effects on the structure of the resulting magnetospheres. We produce families of solutions that span the entire range between the vacuum and the (ideal) Force-Free Electrodynamic solutions. We also compute the amount of dissipation as a fraction of the Poynting flux for pulsars of different angles between the rotation and magnetic axes and conclude that this is at most 20-40% (depending on the non-ideal prescription) in the aligned rotator and 10% in the perpendicular one. We present also the limiting solutions with the property J=ρcJ=\rho c and discuss their possible implication on the determination of the "on/off" states of the intermittent pulsars. Finally, we find that solutions with values of JJ greater than those needed to null E{\bf E}_\parallel locally produce oscillations, potentially observable in the data.

Keywords

Cite

@article{arxiv.1108.2138,
  title  = {Toward a Realistic Pulsar Magnetosphere},
  author = {Constantinos Kalapotharakos and Demosthenes Kazanas and Alice Harding and Ioannis Contopoulos},
  journal= {arXiv preprint arXiv:1108.2138},
  year   = {2015}
}

Comments

26 pages, 12 figures, revised version. Accepted for publication in ApJ

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