Polarization Patterns in Pulsar Radio Emission

TL;DR

This paper investigates complex polarization patterns in pulsar radio emissions, proposing an empirical model that attributes these patterns to perpendicular polarization fluctuations and analyzing their implications for pulsar magnetosphere processes.

Contribution

It introduces an empirical model linking polarization pattern complexity to perpendicular polarization fluctuations and explores potential physical mechanisms behind these fluctuations.

Findings

Complex polarization patterns are caused by perpendicular polarization fluctuations.

Modulation index correlates with polarization pattern complexity.

Intrinsic emission processes are more effective in depolarization than orientation fluctuations.

Abstract

A variety of intriguing polarization patterns are created when polarization observations of the single pulses from radio pulsars are displayed in a two-dimensional projection of the Poincare sphere. In many pulsars, the projections produce two clusters of data points that reside at antipodal points on the sphere. The clusters are formed by fluctuations in polarization amplitude that are parallel to the unit vectors representing the polarization states of the wave propagation modes in the pulsar magnetosphere. In other pulsars, however, the patterns are more complex, resembling annuli and bow ties or bars. The formation of these complex patterns is not understood and largely unexplored. An empirical model of pulsar polarization is used to show that these patterns arise from polarization fluctuations that are perpendicular to the mode vectors. The model also shows that the modulation index of the polarization amplitude is an indicator of polarization pattern complexity. A stochastic version of generalized Faraday rotation can cause the orientation of the polarization vectors to fluctuate and is a possible candidate for the perpendicular fluctuations incorporated in the model. Alternative models indicate that one mode experiences perpendicular fluctuations and the other does not, suggesting that the fluctuations could also be due to a mode-selective random process, such as scattering in the magnetosphere. A polarization stability analysis of the patterns implies that processes intrinsic to the emission are more effective in depolarizing the emission than fluctuations in the orientation of its polarization vector.