Pulsar Electrodynamics: an unsolved problem
Abstract
Pulsar electrodynamics is reviewed emphasizing the role of the inductive electric field in an oblique rotator and the incomplete screening of its parallel component by charges, leaving `gaps' with . The response of the plasma leads to a self-consistent electric field that complements the inductive electric field with a potential field leading to an electric drift and a polarization current associated with the total field. The electrodynamic models determine the charge density, , and the current density, , charge starvation refers to situations where the plasma cannot supply , resulting in a gap and associated particle acceleration and pair creation. It is pointed out that a form of current starvation also occurs implying a new class of gaps. The properties of gaps are discussed, emphasizing that static models are unstable, the role of large-amplitude longitudinal waves, and the azimuthal dependence that arises across a gap in an oblique rotator. Wave dispersion in a pulsar plasma is reviewed briefly, emphasizing its role in radio emission. Pulsar radio emission mechanisms are reviewed, and it is suggested that the most plausible is a form of plasma emission.
Cite
@article{arxiv.1604.03623,
title = {Pulsar Electrodynamics: an unsolved problem},
author = {D. B. Melrose and R. Yuen},
journal= {arXiv preprint arXiv:1604.03623},
year = {2016}
}
Comments
to be published in Journal of Plasma Physics: Special Collection "Plasma Physics of Gamma Ray Emission from Pulsars and their Nebulae"