A full spectral-timing model to map the accretion flow in black hole binaries: the low/hard state of MAXI J1820+070

TL;DR

This paper develops a comprehensive spectral-timing model for black hole binaries in the low/hard state, integrating spectral fitting with variability analysis to better understand accretion flow geometry and relativistic effects.

Contribution

It introduces a full spectral-timing model combining spectral and variability data, accounting for inhomogeneous hot flow and disc truncation, to interpret accretion flow structure in black hole binaries.

Findings

Reproduces double-humped power spectra

Explains energy-dependent high-frequency variability

Models lag-frequency spectrum transitions

Abstract

The nature and geometry of the accretion flow in the low/hard state of black hole binaries is currently controversial. While most properties are generally explained in the truncated disc/hot inner flow model, the detection of a broad residual around the iron line argues for strong relativistic effects from an untruncated disc. Since spectral fitting alone is somewhat degenerate, we combine it with the additional information in the fast X-ray variability and perform a full spectral-timing analysis for NICER and NuSTAR data on a bright low/hard state of MAXI J1820+070. We model the variability with propagating mass accretion rate fluctuations by combining two separate current insights: that the hot flow is spectrally inhomogeneous, and that there is a discontinuous jump in viscous time-scale between the hot flow and variable disc. Our model naturally gives the double-humped shape of the power spectra, and the increasing high-frequency variability with energy in the second hump. Including reflection and reprocessing from a disc truncated at a few tens of gravitational radii quantitatively reproduces the switch in the lag-frequency spectra, from hard lagging soft at low frequencies (propagation through the variable flow) to the soft lagging hard at the high frequencies (reverberation from the hard X-ray continuum illuminating the disc). The viscous time-scale of the hot flow is derived from the model, and we show how this can be used to observationally test ideas about the origin of the jet.