http://arxiv.org/abs/1402.6719
Using the Westerbork Synthesis Radio Telescope (WSRT), we obtained high-time-resolution measurements of the full (linear and circular) polarization of the Crab pulsar. Taken at a resolution of 1/8192 of the 34-ms pulse period (i.e., $4.1 \mu{\rm s}$), the 1.38-GHz linear-polarization measurements are in general agreement with previous lower-time-resolution 1.4-GHz measurements of linear polarization in the main pulse (MP), in the interpulse (IP), and in the low-frequency precursor (LFP). Consistent with previous measurements, we find the MP and LP to be linearly polarized at about $24\%$ and $21\%$, with no discernible difference in polarization position angle. Furthermore, we find no evidence for variation (sweep) in polarization position angle over the MP, the IP, or the LFP. However, the main pulse exhibits a small but statistically significant quadratic variation in the degree of linear polarization. In addition, we detect weak circular polarization in the main pulse and interpulse, and strong ($\approx 20\%$) circular polarization in the low-frequency precursor, which also exhibits very strong($\approx 98\%$) linear polarization at a position angle about 40 degrees from that of the MP or IP. The pulse-mean polarization properties are consistent with the LFP being a low-altitude core component and the MP and IP being high-altitude caustic components. However, current models for the MP and IP emission do not readily account for the observed absence of pronounced polarization changes across the pulse.
Peripheral to the polarimetry, we find high-frequency substructure in the profile of the main pulse, presumably due to giant radio pulses. In addition, we measure IP and LFP pulse phases relative to the MP that are consistent with recent measurements, which have shown that the phases of these pulse components are evolving with time.
A. Slowikowska, B. Stappers, A. Harding, et. al.
Fri, 28 Feb 14
33/54