Core and Conal Component Analysis of Pulsar B1933+16 --- Investigation of the Segregated Modes

TL;DR

This study provides a detailed polarimetric analysis of pulsar B1933+16, revealing insights into its core and conal emission modes, polarization characteristics, and emission heights, supporting the coherent curvature radiation model.

Contribution

It offers a comprehensive high-resolution polarimetric analysis of pulsar B1933+16, identifying emission modes and heights, and comparing core and conal regions within a unified framework.

Findings

Core comprises two parts associated with different polarization modes.

Emission heights are approximately 200 km for both core and conal regions.

Radio emission is consistent with coherent curvature radiation by charged solitons.

Abstract

Radio pulsar B1933+16 is brightest core-radiation dominated pulsar in the Arecibo sky, and here we carry out a comprehensive high resolution polarimetric study of its radiation at both 1.5 and 4.6 GHz. At 1.5 GHz, the polarization is largely compatible with a rotating-vector model with $\alpha$ and $\beta$ values of 125 and --1.2$^{\circ}$, such that the core and conal regions can be identified with the primary and secondary polarization modes and plausibly with the extraordinary and ordinary propagation modes. Polarization modal segregation of profiles shows that the core is comprised of two parts which we associate with later X-mode and earlier O-mode emission. Analysis of the broad microstructures under the core shows that they have similar timescales to those of the largely conal radiation of other pulsars studied earlier. Aberration/retardation analysis was here possible for both the conal and core radiation and showed average physical emission heights of about 200 km for each. Comparison with other core-cone pulsars suggests that the core and conal emission arises from similar heights. Assuming the inner vacuum gap model, we note that at these emission altitudes the frequency of the observed radiation $\nu_{obs}$ is less than the plasma frequency $\nu_p$. We then conclude that the radio emission properties are consistent with the theory of coherent curvature radiation by charged solitons where the condition $\nu_{obs} < \nu_{p}$ is satisfied. However, the differences that exist between core and conal emission in their geometric locations within a pulse, polarization and modulation properties are yet to be understood.