Upgraded Giant Metrewave Radio Telescope timing of NGC 1851A: a possible millisecond pulsar-neutron star system

TL;DR

This study presents precise timing measurements of a millisecond pulsar in NGC 1851, refining system parameters and suggesting the companion may also be a neutron star, highlighting efficient recycling with minimal mass transfer.

Contribution

The paper provides the first detailed timing analysis of PSR J0514-4002A in NGC 1851, improving mass measurements and exploring the nature of its companion.

Findings

Refined total mass of the binary system to 2.4730(6) solar masses.

Measured pulsar mass as 1.25(+0.05/-0.06) solar masses.

Detected proper motion crucial for interpreting relativistic parameters.

Abstract

(abridged) In this work we present the results of one year of upgraded Giant Metrewave Radio Telescope timing measurements of PSR~J0514$-$4002A, a 4.99-ms pulsar in a 18.8-day, eccentric ($e \, =\, 0.89$) orbit with a massive companion located in the globular cluster NGC~1851. Combining these data with earlier Green Bank Telescope data, we greatly improve the precision of the rate of advance of periastron, $\dot{\omega} \, = \, 0.0129592(16)\, \deg \, \rm yr^{-1}$ which, assuming the validity of general relativity, results in a much refined measurement of the total mass of the binary, $M_{\rm tot} \, = \, 2.4730(6) \, M_{\odot}$. Additionally, we measure the Einstein delay parameter, $\gamma\,, = \, 0.0216(9) \, \rm s$. Furthermore, we measure the proper motion of the system ($\mu_{\alpha} \, = \, 5.19(22)$ and $\mu_{\delta} = -0.56(25)\rm~mas ~ yr^{-1}$), which is not only important for analyzing its motion in the cluster, but is also essential for a proper interpretation of $\gamma$, given the latter parameter's correlation with the variation of the projected semi-major axis. The measurements of $\gamma$ and the proper motion enable a separation of the system component masses: we obtain a pulsar mass of $M_{p} \, = \, 1.25^{+0.05}_{-0.06} \, M_{\odot}$ and a companion mass of $M_{c} \, = \, 1.22^{+0.06}_{-0.05} \, M_{\odot}$. This raises the possibility that the companion is also a neutron star. Searches for radio pulsations from the companion have thus far been unsuccessful, hence we cannot confirm the latter hypothesis. The low mass of this millisecond pulsar - one of the lowest ever measured for such objects - clearly indicates that the recycling process can be achieved with a relatively small amount of mass transfer.