A rapid optical and X-ray timing study of the neutron star X-ray binary Swift J1858.6-0814

TL;DR

This study conducts a rapid timing analysis of optical and X-ray observations of the neutron star X-ray binary Swift J1858.6-0814, revealing complex correlations and emission mechanisms during outburst phases.

Contribution

It provides the first detailed timing analysis linking optical and X-ray variability, supporting the hybrid inner hot accretion flow model for this system.

Findings

Optical flares show slow 'blue' and fast 'red' components linked to different emission processes.

Optical and X-ray correlations vary over time, indicating changing dominant emission mechanisms.

Timing analysis supports the hybrid accretion flow model with multiple emission components.

Abstract

We present a rapid timing analysis of optical (HiPERCAM and ULTRACAM) and X-ray (NICER) observations of the X-ray transient Swift J1858.6-0814 during 2018 and 2019. The optical light curves show relatively slow, large amplitude (~1 mags in g$_s$) `blue' flares (i.e. stronger at shorter wavelengths) on time-scales of ~minutes as well as fast, small amplitude (~0.1 mag in g$_s$) `red' flares (i.e. stronger at longer wavelengths) on time-scales of ~seconds. The `blue' and `red' flares are consistent with X-ray reprocessing and optically thin synchrotron emission, respectively, similar to what is observed in other X-ray binaries. The simultaneous optical versus soft- and hard-band X-ray light curves show time- and energy dependent correlations. The 2019 March 4 and parts of the June data show a nearly symmetric positive cross correlations (CCFs) at positive lags consistent with simple X-ray disc reprocessing. The soft- and hard-band CCFs are similar and can be reproduced if disc reprocessing dominates in the optical and one component (disc or synchrotron Comptonization) dominates both the soft and hard X-rays. A part of the 2019 June data shows a very different CCFs. The observed positive correlation at negative lag in the soft-band can be reproduced if the optical synchrotron emission is correlated with the hot flow X-ray emission. The observed timing properties are in qualitative agreement with the hybrid inner hot accretion flow model, where the relative role of the different X-ray and optical components that vary during the course of the outburst, as well as on shorter time-scales, govern the shape of the optical/X-ray CCFs.