Basic parameters of the helium accreting X-ray bursting neutron star in 4U 1820-30

TL;DR

This study re-analyzes X-ray bursts from 4U 1820-30 to estimate the neutron star's mass and radius, finding constraints that depend on the assumed atmospheric composition and confirming the system's distance.

Contribution

It applies the direct cooling tail method to X-ray burst data, providing new constraints on the neutron star's parameters in 4U 1820-30.

Findings

Neutron star radius is estimated between 10-12 km for masses below 1.7 M_sun.

Distance to the system is constrained to 6.5±0.5 kpc.

Atmospheric composition assumptions significantly affect the parameter constraints.

Abstract

The ultracompact low-mass X-ray binary 4U 1820-30 situated in the globular cluster NGC 6624 has an orbital period of only $\approx$11.4 min which likely implies a white dwarf companion. The observed X-ray bursts demonstrate a photospheric radius expansion phase and therefore are believed to reach the Eddington luminosity allowing us to estimate the mass and the radius of the neutron star (NS) in this binary. Here we re-analyse all Rossi X-ray Timing Explorer observations of the system and confirm that almost all the bursts took place during the hard persistent state of the system. This allows us to use the recently developed direct cooling tail method to estimate the NS mass and radius. However, because of the very short, about a second, duration of the cooling tail phases that can be described by the theoretical atmosphere models, the obtained constraints on the NS radius are not very strict. Assuming a pure helium NS atmosphere we found that the NS radius is in the range 10-12 km, if the NS mass is below 1.7 $M_\odot$, and in a wider range of 8-12 km for a higher 1.7-2.0 $M_\odot$ NS mass. The method also constrains the distance to the system to be 6.5$\pm$0.5 kpc, which is consistent with the distance to the cluster. For the solar composition atmosphere, the NS parameters are in strong contradiction with the generally accepted range of possible NS masses and radii.