The impact on astrometry by solar-wind effect in pulsar timing

TL;DR

This paper investigates how solar wind affects pulsar astrometry measurements via timing, demonstrating that solar wind parameters can bias position and parallax estimates, and proposing methods to mitigate these effects for improved accuracy.

Contribution

It introduces a comprehensive analysis of solar wind influence on pulsar timing astrometry and proposes joint measurement techniques using multi-frequency data to improve parameter estimation.

Findings

Solar wind significantly biases pulsar position and parallax estimates.

Multi-frequency data reduces parameter correlation and improves measurement precision.

Reprocessed data confirms solar wind effects are consistent with low-frequency observations.

Abstract

Astrometry of pulsars, particularly their distances, serves as a critical input for various astrophysical experiments using pulsars. Pulsar timing is a primary approach for determining a pulsar's position, parallax, and distance. In this paper, we explore the influence of the solar wind on astrometric measurements obtained through pulsar timing, focusing on its potential to affect the accuracy of these parameters. Using both theoretical calculation and mock-data simulations, we demonstrate a significant correlation between the pulsar position, annual parallax and the solar-wind density parameters. This correlation strongly depends on the pulsar's ecliptic latitude. We show that fixing solar-wind density to an arbitrary value in the timing analysis can introduce significant bias in the estimated pulsar position and parallax, and its significance is highly dependent on the ecliptic latitude of the pulsar and the timing precision of the data. For pulsars with favourable ecliptic latitude and timing precision, the astrometric and solar-wind parameters can be measured jointly with other timing parameters using single-frequency data. The parameter correlation can be mitigated by using multi-frequency data, which also significantly improves the measurement precision of these parameters; this is particularly important for pulsars at a medium or high ecliptic latitude. Additionally, for a selection of pulsars we reprocess their EPTA Data Release 2 data to include modelling of solar-wind effect in the timing analysis. This delivers significant measurements of both parallax and solar-wind density, the latter of which are consistent with those obtained at low-frequency band. In the future, combining pulsar timing data at gigahertz and lower frequencies will probably deliver the most robust and precise measurements of astrometry and solar wind properties in pulsar timing.