Eclipses of jets and discs of X-ray binaries as a powerful tool for understanding jet physics and binary parameters

TL;DR

This paper explores how eclipses in X-ray binary systems affect jet emissions and how these effects can be used to infer system parameters and jet physics, with predictions for observational signatures across different wavelengths.

Contribution

It provides a detailed calculation of eclipse effects on jet emissions and proposes using these effects to measure binary parameters and jet structures.

Findings

Eclipses cause 5-10% reductions in jet emission over various wavelengths.

Deep eclipses are possible in high-inclination, moderate mass ratio systems.

Radio and optical/infrared observations can identify promising systems for eclipse detection.

Abstract

We calculate the expected effects on the spectral energy distributions and light curves in X-ray binary jets from eclipses by the donor stars. Jets will be eclipsed for all inclination angles, with just the height along the jet where the eclipse takes place being set by the orbital parameters. Typically, eclipses will lead to 5-10\% reductions in the jet emission over a range of a factor of few in wavelength with a periodic modulation. In ideal systems with high inclination angles, relatively even mass ratios, and modest jet speeds, the eclipses may be deeper. We discuss how eclipses can be used to measure binary system parameters, as well as the height of the bases of the jets. We also discuss how, with data sets that will likely require future facilities, more detailed tests of models of jet physics could be made, by establishing deviations from the standard recipes for compact conical flat spectrum jets, and by determining the ingress and egress durations of the eclipses and measuring the transverse size of the jets. We provide representative calculations of expectations for different classes of systems, demonstrating that the most promising target for showing this effect in the radio band are the longer period "atoll"-class neutron star X-ray binaries, while in the optical and infrared bands, the best candidates are likely to be the most edge-on black hole X-ray binaries. We also discuss the effects of the outer accretion disc eclipsing the inner jet.