Electrodynamics and Radiation from Rotating Neutron Star Magnetospheres

• Published in: Universe (Basel) Vol. 6; no. 1; p. 15
• Main Author: Pétri, Jérôme
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.01.2020; MDPI
• Subjects: Astrophysics; Coordinate transformations; corotation; electrodynamics; Electromagnetic fields; Electromagnetism; Emission measurements; Magnetic fields; magnetosphere; Neutron stars; Neutrons; Physics; plasma; Radiation; Spacetime; Theory of relativity; Velocity; corotation; magnetosphere; neutron stars; plasma; radiation; electrodynamics
• ISSN: 2218-1997; 2218-1997
• DOI: 10.3390/universe6010015

Neutron stars are compact objects rotating at high speed, up to a substantial fraction of the speed of light (up to 20% for millisecond pulsars) and possessing ultra-strong electromagnetic fields (close to and sometimes above the quantum critical field of 4.4 × 10 9 T ). Moreover, due to copious e ± pair creation within the magnetosphere, the relativistic plasma surrounding the star is forced into corotation up to the light cylinder where the corotation speed reaches the speed of light. The neutron star electromagnetic activity is powered by its rotation which becomes relativistic in the neighborhood of this light cylinder. These objects naturally induce relativistic rotation on macroscopic scales about several thousands of kilometers, a crucial ingredient to trigger the central engine as observed on Earth. In this paper, we elucidate some of the salient features of this corotating plasma subject to efficient particle acceleration and radiation, emphasizing several problems and limitations concerning current theories of neutron star magnetospheres. Relativistic rotation in these systems is indirectly probed by the radiation produced within the magnetosphere. Depending on the underlying assumptions about particle motion and radiation mechanisms, different signatures on their light curves, spectra, pulse profiles and polarization angles are expected in their broadband electromagnetic emission. We show that these measurements put stringent constraints on the way to describe particle electrodynamics in a rotating neutron star magnetosphere.