Magnetar counterparts, kinematics and birth sites with HST and JWST

Abstract

Magnetars are highly magnetised, isolated neutron stars with uncertain formation channels. They comprise a potentially significant fraction of the young neutron star population in the Milky Way, and are implicated in the explosion mechanisms of some of the most powerful explosions in nature. We aim to identify magnetars in the near-infrared with Hubble Space Telescope (HST) and James Webb Space Telescope (JWST) imaging, in order to measure their proper motions and search for their birth sites. Candidate infrared counterparts are selected based on variability, colours and proper motions which are outliers with respect to sources in the field. Proper motions are obtained by tying HST and JWST images to the Gaia absolute astrometric reference frame. We newly identify infrared counterparts for PSRJ1622-4950, 1RXSJ170849.0-400910 and CXOUJ164710.2-455216, representing a substantial increase in the population. The past trajectory of the 1RXSJ170849.0-400910-associated source coincides with the supernova remnant G346.6-0.2. The transverse velocity distribution is found to be marginally inconsistent with young pulsars, due primarily to a dearth of high velocity magnetars. A candidate birth site is identified in nearly every case. We show, based on the inferred kinematic ages, that magnetar characteristic ages may frequently be lower than the true age, but caution that this depends on the reliability of the birth site associations. We conclude that magnetars are broadly similar in terms of their kinematics and birth sites to the wider Galactic neutron star population, consistent with magnetar formation being a common outcome of core-collapse. However, tentative evidence for a dearth of high-velocity magnetars is emerging. If real, this may arise from physical differences in the progenitor population giving rise to magnetars, or from differences in their post-formation velocity evolution.