Tracing the reverberation lag in the hard state of black hole X-ray binaries

TL;DR

This study analyzes X-ray lags in black hole X-ray binaries, revealing how reverberation lags evolve with luminosity and providing insights into the accretion disc geometry during outbursts.

Contribution

It offers the first detailed characterization of reverberation lag evolution during the hard state of a black hole binary using broad-band X-ray observations.

Findings

Reverberation lag amplitude decreases with increasing luminosity.

Disc component leads the power law at low frequencies.

Soft reverberation lag is consistently detected at high frequencies.

Abstract

We report results obtained from a systematic analysis of X-ray lags in a sample of black hole X-ray binaries, with the aim of assessing the presence of reverberation lags and studying their evolution during outburst. We used XMM-Newton and simultaneous RXTE observations to obtain broad-band energy coverage of both the disc and the hard X-ray Comptonization components. In most cases the detection of reverberation lags is hampered by low levels of variability signal-to-noise ratio (e.g. typically when the source is in a soft state) and/or short exposure times. The most detailed study was possible for GX 339-4 in the hard state, which allowed us to characterize the evolution of X-ray lags as a function of luminosity in a single source. Over all the sampled frequencies (~0.05-9 Hz) we observe the hard lags intrinsic to the power law component, already well-known from previous RXTE studies. The XMM-Newton soft X-ray response allows us to detail the disc variability. At low-frequencies (long time scales) the disc component always leads the power law component. On the other hand, a soft reverberation lag (ascribable to thermal reprocessing) is always detected at high-frequencies (short time scales). The intrinsic amplitude of the reverberation lag decreases as the source luminosity and the disc-fraction increase. This suggests that the distance between the X-ray source and the region of the optically-thick disc where reprocessing occurs, gradually decreases as GX 339-4 rises in luminosity through the hard state, possibly as a consequence of reduced disc truncation.