Using long-term millisecond pulsar timing to obtain physical characteristics of the bulge globular cluster Terzan 5

TL;DR

This study uses long-term millisecond pulsar timing to accurately determine the physical properties of the globular cluster Terzan 5, revealing its dense core, mass distribution, and implications for its origin and evolution.

Contribution

It introduces a novel method of using pulsar accelerations to measure cluster properties independently of optical observations, providing new insights into Terzan 5's structure and history.

Findings

Core density of 1.58×10^6 M_sun/pc^3

Total mass approximately 3.0×10^5 M_sun

Upper limit for central black hole mass of 3.0×10^4 M_sun

Abstract

Over the past decade the discovery of three unique stellar populations and a large number of confirmed pulsars within the globular cluster Terzan 5 has raised questions over its classification. Using the long-term radio pulsar timing of 36 millisecond pulsars in the cluster core, we provide new measurements of key physical properties of the system. As Terzan 5 is located within the galactic bulge, stellar crowding and reddening make optical and near infrared observations difficult. Pulsar accelerations, however, allow us to study the intrinsic characteristics of the cluster independent of reddening and stellar crowding and probe the mass density profile without needing to quantify the mass to light ratio. Relating the spin and orbital periods of each pulsar to the acceleration predicted by a King model, we find a core density of $1.58\times$10$^6$ M$_\odot$ pc$^{-3}$, a core radius of 0.16 pc, a pulsar density profile $n\propto r^{-3.14}$, and a total mass of M$_{\rm T}$($R_\perp<$1.0 pc)$\simeq3.0\times$10$^5$ M$_\odot$ assuming a cluster distance of 5.9 kpc. Using this information we argue against Terzan 5 being a disrupted dwarf galaxy and discuss the possibility of Terzan 5 being a fragment of the Milky Way's proto-bulge. We also discuss whether low-mass pulsars were formed via electron capture supernovae or exist in a core full of heavy white dwarfs and hard binaries. Finally we provide an upper limit for the mass of a possible black hole at the core of the cluster of 3.0$\times$10$^4$ M$_\odot$.