An application of the Ghosh & Lamb model to the accretion powered X-ray pulsar X Persei

TL;DR

This study applies the Ghosh & Lamb accretion torque model to long-term X-ray observations of X Persei, revealing a high magnetic field strength and estimating the neutron star's mass around 2 solar masses.

Contribution

It demonstrates the applicability of the Ghosh & Lamb model to X Persei's pulse period changes and provides new estimates of the neutron star's magnetic field and mass.

Findings

Magnetic field strength of (4-25) x 10^{13} G fits observations.

Neutron star mass estimated at approximately 2 solar masses.

Negative correlation between spin-up/down rate and flux explained by accretion torque model.

Abstract

The accretion-induced pulse-period changes of the Be/X-ray binary pulsar X Persei were investigated over a period of 1996 January to 2017 September. This study utilized the monitoring data acquired with the RXTE/ASM in 1.5$-$12 keV and MAXI/GSC in 2$-$20 keV. The source intensity changed by a factor of 5$-$6 over this period. The pulsar was spinning down for 1996$-$2003, and has been spinning up since 2003, as already reported. The spin up/down rate and the 3$-$12 keV flux, determined every 250 d, showed a clear negative correlation, which can be successfully explained by the accretion torque model proposed by Ghosh & Lamb (1979). When the mass, radius and distance of the neutron star are allowed to vary over a range of 1.0$-$2.4 solar masses, 9.5$-$15 km, and 0.77$-$0.85 kpc, respectively, the magnetic field strength of $B=(4-25) \times10^{13}\ \rm G$ gave the best fits to the observation. In contrast, the observed results cannot be explained by the values of $B\sim10^{12}\ \rm G$ previously suggested for X Persei, as long as the mass, radius, and distance are required to take reasonable values. Assuming a distance of $0.81\pm0.04$ kpc as indicated by optical astrometry, the mass of the neutron star is estimated as $M=2.03\pm0.17$ solar masses.