Spectral hardening as a viable alternative to disc truncation in black hole state transitions

TL;DR

This study shows that spectral hardening, represented by an increasing color correction factor, can explain black hole state transitions without requiring the inner disc radius to change, challenging the traditional disc truncation model.

Contribution

It introduces spectral hardening as an alternative explanation for state transitions, reducing reliance on disc truncation assumptions in black hole binaries.

Findings

A variable f_col can explain spectral evolution during state transitions.

The L_disc-T_eff^4 relation is recovered with evolving f_col.

Spectral hardening can account for state changes without disc truncation.

Abstract

Constraining the accretion flow geometry of black hole binaries in outburst is complicated by the inability of simplified multi-colour disc models to distinguish between changes in the inner disc radius and alterations to the emergent spectrum, parameterised by the phenomenological colour correction factor, f_col. We analyse Rossi X-ray Timing Explorer observations of the low mass Galactic black hole X-ray binary, GX 339-4, taken over seven epochs when the source was experiencing a state transition. The accretion disc component is isolated using a pipeline resulting in robust detections for disc luminosities, 0.001 < L_disc / L_Edd < 0.5. Assuming that the inner disc remains situated at the innermost stable circular orbit over the course of a state transition, we measure the relative degree of change in f_col required to explain the spectral evolution of the disc component. A variable f_col that increases by a factor of ~ 2.0 - 3.5 as the source transitions from the high/soft state to the low/hard state can adequately explain the observed disc spectral evolution. For the observations dominated by a disc component, the familiar scaling between the disc luminosity and effective temperature, L_disc ~ T_eff^4, is observed; however, significant deviations from this relation appear when GX 339-4 is in the hard intermediate and low/hard states. Allowing for an evolving f_col between spectral states, the L_disc-T_eff^4 law is recovered over the full range of disc luminosities, although this depends heavily on the physically conceivable range of f_col. We demonstrate that physically reasonable changes in f_col provide a viable description for multiple state transitions of a black hole binary without invoking radial motion of the inner accretion disc.