The Galactic population of magnetars : a simulation-based inference study
Abstract
Population synthesis modeling of the observed dynamical and physical properties of a population is a highly effective method for constraining the underlying birth parameters and evolutionary tracks. In this work, we apply a population synthesis model to the canonical magnetar population to gain insight into the parent population. We utilize simulation-based inference to reproduce the observed magnetar population with a model which takes into account the secular evolution of the force-free magnetosphere and magnetic field decay simultaneously and self-consistently. Our observational constraints are such that no magnetar is detected through their persistent emission when convolving the simulated populations with the XMM-Newton EPIC-pn Galactic plane observations, and that all of the 30 known magnetars are discovered through their bursting activity in the last 50 years. Under these constraints, we find that, within 95 % credible intervals, the birth rate of magnetars to be 1.8+2.6-0.6 kyr-1, and lead to having 10.7+18.8-4.4 % of neutron stars born as magnetars. We also find a mean magnetic field at birth (μb is in T) (μb) = 10.2+0.1-0.2, a magnetic field decay slope αd = 1.9 +0.9-1.3, and timescale τd = 17.9+24.1-14.5 kyr, in broad agreement with previous estimates. We conclude this study by exploring detection prospects: an all-sky survey with XMM-Newton would potentially allow to get around 7 periodic detections of magnetars, with approximately 150 magnetars exceeding XMM-Newton's flux threshold, and the upcoming AXIS experiment should allow to double these detections.
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