On the nature of the Cygnus X-2 like Z-track sources

TL;DR

This paper explains the behavior of Cygnus X-2 like Z-track sources using an extended accretion disk corona model, linking radiation pressure, jet formation, and unstable nuclear burning to observed spectral and timing features.

Contribution

It introduces a comprehensive model connecting radiation pressure, disk disruption, jet launching, and nuclear burning in Cygnus X-2 like sources, supported by spectral and QPO analysis.

Findings

High radiation pressure correlates with jet launching.

Flaring results from unstable nuclear burning.

Inner disk radius varies with radiation pressure.

Abstract

Based on the results of applying the extended ADC emission model for low mass X-ray binaries to three Z-track sources: GX340+0, GX5-1 and CygX-2, we propose an explanation of the CygnusX-2 like Z-track sources. The Normal Branch is dominated by the increasing radiation pressure of the neutron star caused by a mass accretion rate that increases between the soft apex and the hard apex. The radiation pressure continues to increase on the Horizontal Branch becoming several times super-Eddington. We suggest that this disrupts the inner accretion disk and that part of the accretion flow is diverted vertically forming jets which are detected by their radio emission on this part of the Z-track. We thus propose that high radiation pressure is the necessary condition for the launching of jets. On the Flaring Branch there is a large increase in the neutron star blackbody luminosity at constant mass accretion rate indicating an additional energy source on the neutron star. We find that there is good agreement between the mass accretion rate per unit emitting area of the neutron star mdot at the onset of flaring and the theoretical critical value at which burning becomes unstable. We thus propose that flaring in the CygnusX-2 like sources consists of unstable nuclear burning. Correlation of measurements of kilohertz QPO frequencies in all three sources with spectral fitting results leads to the proposal that the upper kHz QPO is an oscillation always taking place at the inner accretion disk edge, the radius of which increases due to disruption of the disk by the high radiation pressure of the neutron star.