EP250207b is not a collapsar fast X-ray transient. Is it due to a compact object merger?

TL;DR

This study investigates the nature of FXT EP250207b, providing evidence against a collapsar origin and supporting a binary compact object merger, with multi-wavelength data fitting a slightly off-axis afterglow model.

Contribution

It presents the first multi-wavelength analysis suggesting a compact object merger origin for an FXT, challenging the collapsar association for this transient.

Findings

EP250207b is unlikely to be a collapsar-related event.

The data are consistent with a binary compact object merger.

Late-time emission may originate from a globular cluster or dwarf galaxy core.

Abstract

Fast X-ray Transients (FXTs) are short-lived extra-galactic X-ray sources. Recent progress through multi-wavelength follow-up of Einstein Probe discovered FXTs has shown that several are related to collapsars, which can also produce gamma-ray bursts (GRBs). In this paper we investigate the nature of the FXT EP250207b. The VLT/MUSE spectra of a nearby (15.9 kpc in projection) lenticular galaxy reveal no signs of recent star formation. If this galaxy is indeed the host, EP250207b lies at a redshift of z=0.082, implying a peak observed absolute magnitude for the optical counterpart of M_r=-14.5. At the time when supernovae (SNe) would peak, it is substantially fainter than all SN types. These results are inconsistent with a collapsar origin for EP250207b. The properties favour a binary compact object merger driven origin. The X-ray, optical and radio observations are compared with predictions of several types of extra-galactic transients, including afterglow and kilonova models. The data can be fit with a slightly off-axis viewing angle afterglow. However, the late-time (~30 day) optical/NIR counterpart is too bright for the afterglow and also for conventional kilonova models. This could be remedied if that late emission is due to a globular cluster or the core of a (tidally disrupted) dwarf galaxy. If confirmed, this would be the first case where the multi-wavelength properties of an FXT are found to be consistent with a compact object merger origin, increasing the parallels between FXTs and GRBs. We finally discuss if the source could originate in a higher redshift host galaxy.