Pulse Profiles and Polarization of Terzan 5 Pulsars

TL;DR

This study combines extensive archival data to analyze the polarization, flux densities, and magnetic field mapping of 32 millisecond pulsars in Terzan 5, revealing magnetic field variability and pulsar luminosity characteristics.

Contribution

It provides high S/N profiles, precise rotation measures, and magnetic field mapping for pulsars in Terzan 5, and characterizes their flux densities, spectral indices, and luminosity function, advancing understanding of pulsar populations in globular clusters.

Findings

Mapped Galactic magnetic field variability at sub-parsec scales.

Measured flux densities ranging from 10 μJy to 2 mJy.

Determined a pulsar spectral index of -1.35, flatter than typical.

Abstract

Terzan 5 is a rich globular cluster within the galactic bulge that contains 39 known millisecond pulsars, the largest known population of any globular cluster. The Terzan 5 pulsars are faint, so that individual observations of most of the pulsars have too little signal-to-noise (S/N) to measure reliable flux density or polarization information. We combined over 5.2\,days of archival data, at each of 1.5\,GHz and 2.0\,GHz, taken with the Green Bank Telescope over the past 11\,years. We created high S/N profiles for 32 of the pulsars and determined precise rotation measures (RMs) for 28 of them. We used the RMs, and the known pulsar positions and dispersion measures (DMs), to map the projected parallel component of the Galactic magnetic field toward the cluster. The $\langle B_{||}\rangle$ shows a rough gradient of $\sim$6\,nG/arcsec ($\sim$160\,nG/parsec), or fractionally, a change of $\sim$20$\%$ in the right ascension direction across the cluster, implying Galactic magnetic field variability at sub-parsec scales. We also measured average flux densities $S_\nu$ for the pulsars, ranging from $\sim$10\,$\mu$Jy to $\sim$2\,mJy, and an average spectral index $\alpha = -1.35$, where $S_\nu \propto \nu^{\alpha})$. This spectral index is flatter than most known pulsars, likely a selection effect due to the high frequencies used in pulsar searches to mitigate dispersion and scattering. The inferred pulsar luminosity function is roughly power-law, with slope $(d\log N)/(d\log L) = -1$ at the high-luminosity end. At the low-luminosity end, there are incompleteness effects implying that Terzan 5 contains many more pulsars to be found.