Connery Chen, Yihan Wang, Bing Zhang

Neutron star (NS) mergers, including both binary NS mergers and black hole - NS mergers, are multi-messenger sources detectable in both gravitational waves (GWs) and electromagnetic (EM) radiation. The expected EM emission signatures depend on the source's progenitor, merger remnant, and observer's line of sight (LoS). Widely discussed EM counterparts of NS mergers have been focused in the gamma-ray (in terms of short-duration gamma-ray bursts) and optical (in terms of kilonova) bands. In this paper, we show that X-ray emission carries unique post-merger signatures that are inaccessible in other EM bands and plays an important role in understanding the physics and geometry of these mergers. We consider several binary progenitor and central engine models and investigate X-ray emission signatures from the prompt phase immediately after the merger to the afterglow phase extending years later. For the prompt phase, we devise a general method for computing phenomenological X-ray light curves and spectra for structured jets viewed from any LoS, which can be applied to X-ray observations of NS mergers to constrain the geometry. The geometric constraints can in turn be used to model the afterglow and estimate a peak time and flux -- to preemptively determine afterglow characteristics would be monumental for follow-up observation campaigns of future GW sources. Finally, we provide constraints on the time window for X-ray counterpart searches of NS mergers across a range of luminosity distances and detector sensitivities.