Wide-band Profile Domain Pulsar Timing Analysis

TL;DR

This paper advances pulsar timing analysis by integrating wide-band effects and profile evolution models, leading to up to 40% improved timing precision, crucial for gravitational wave detection.

Contribution

It introduces a novel profile domain framework with efficient Bayesian sampling methods for wide-band pulsar timing analysis, accounting for profile evolution and shape variations.

Findings

Profile domain analysis improves timing precision by up to 40%.

Smooth DM variation models enhance precision by up to 30%.

Detected intrinsic pulse shape variations affecting timing measurements.

Abstract

We extend profile domain pulsar timing to incorporate wide-band effects such as frequency-dependent profile evolution and broadband shape variation in the pulse profile. We also incorporate models for temporal variations in both pulse width and in the separation in phase of the main pulse and interpulse. We perform the analysis with both nested sampling and Hamiltonian Monte Carlo methods. In the latter case we introduce a new parameterisation of the posterior that is extremely efficient in the low signal-to-noise regime and can be readily applied to a wide range of scientific problems. We apply this methodology to a series of simulations, and to between seven and nine yr of observations for PSRs J1713$+$0747, J1744$-$1134, and J1909$-$3744 with frequency coverage that spans 700-3600MHz. We use a smooth model for profile evolution across the full frequency range, and compare smooth and piecewise models for the temporal variations in DM. We find the profile domain framework consistently results in improved timing precision compared to the standard analysis paradigm by as much as 40% for timing parameters. Incorporating smoothness in the DM variations into the model further improves timing precision by as much as 30%. For PSR J1713+0747 we also detect pulse shape variation uncorrelated between epochs, which we attribute to variation intrinsic to the pulsar at a level consistent with previously published analyses. Not accounting for this shape variation biases the measured arrival times at the level of $\sim$30ns, the same order of magnitude as the expected shift due to gravitational-waves in the pulsar timing band.