High-fidelity radio astronomical polarimetry using a millisecond pulsar as a polarized reference source

TL;DR

This paper introduces a new polarimetric calibration method using a stable millisecond pulsar as a reference, significantly improving timing precision and enabling precise measurements of pulsar parameters over long periods.

Contribution

The authors present a novel calibration technique that reduces systematic errors in pulsar timing, applicable to long-term observations and future large-scale radio telescopes.

Findings

Achieved timing residuals with an uncertainty of 880 ns, twice as precise as conventional methods.

First significant measurements of secular variations in pulsar orbital parameters.

Demonstrated potential to improve the sensitivity of pulsar timing arrays by reducing instrumental polarization errors.

Abstract

A new method of polarimetric calibration is presented in which the instrumental response is derived from regular observations of PSR J0437-4715 based on the assumption that the mean polarized emission from this millisecond pulsar remains constant over time. The technique is applicable to any experiment in which high-fidelity polarimetry is required over long time scales; it is demonstrated by calibrating 7.2 years of high-precision timing observations of PSR J1022+1001 made at the Parkes Observatory. Application of the new technique followed by arrival time estimation using matrix template matching yields post-fit residuals with an uncertainty-weighted standard deviation of 880 ns, two times smaller than that of arrival time residuals obtained via conventional methods of calibration and arrival time estimation. The precision achieved by this experiment yields the first significant measurements of the secular variation of the projected semi-major axis, the precession of periastron, and the Shapiro delay; it also places PSR J1022+1001 among the ten best pulsars regularly observed as part of the Parkes Pulsar Timing Array (PPTA) project. It is shown that the timing accuracy of a large fraction of the pulsars in the PPTA is currently limited by the systematic timing error due to instrumental polarization artifacts. More importantly, long-term variations of systematic error are correlated between different pulsars, which adversely affects the primary objectives of any pulsar timing array experiment. These limitations may be overcome by adopting the techniques presented in this work, which relax the demand for instrumental polarization purity and thereby have the potential to reduce the development cost of next-generation telescopes such as the Square Kilometre Array.