A variable ADAF disk model for X-ray binary systems

TL;DR

This paper introduces a variable ADAF disk model for X-ray binary systems that explains observed outburst cycles, spectral states, and emission features by incorporating a dynamic inner ADAF region.

Contribution

The model uniquely combines a variable ADAF with a thin disk to unify spectral state transitions and emission features in X-ray binaries, extending to AGN phenomena.

Findings

Explains X-ray outburst phases with ADAF cycle dynamics.

Unifies Fe emission lines with truncated disk observations.

Accounts for periodic behavior in neutron star systems.

Abstract

We propose a variable ADAF disk model for X-ray binary systems. In this model, the accretion flow consists of an outer thin disk and an inner optically thick advection-dominated accretion flow (ADAF) torus. The size of the turbulent ADAF is variable. A complete cycle of ADAF contraction, transition to a thin disk, and subsequent re-expansion corresponds to the rapid rise, peak, and decay phases observed in the X-ray outbursts of black hole binaries. This cycle also tracks the canonical evolution through the low-hard, high-soft, and back to the low-hard state in the hardness-intensity diagram. The model unifies the presence of near-ISCO Fe emission lines with the truncated disk paradigm, as observed in the black hole system GX 339-4. It explains the 35-day period in the neutron star system Her X-1 more effectively through variable ADAF sizes than through a precessing disk. This variable ADAF framework may be extended to explain similar phenomena in active galactic nuclei.