4.7 Article

Modelling spin evolution of magnetars

Journal

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY
Volume 509, Issue 1, Pages 634-657

Publisher

OXFORD UNIV PRESS
DOI: 10.1093/mnras/stab2677

Keywords

stars: magnetars; stars: magnetic field; stars: neutron; pulsars: general

Funding

  1. Department of Physics and Astronomy (IFA) at Aarhus University

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The study investigates the spin evolution of magnetars and potential evolutionary links to other species of neutron stars. By synthesizing magnetar populations and comparing them to observations, it is found that the B-field decay must be exponential or superexponential, and the initial spin period should be less than 2 seconds. Additionally, magnetars may be linked to XDINSs evolutionarily, but are unlikely to evolve into RRATs.
The origin and fate of magnetars [young, extremely magnetized neutron stars (NSs)] remains unsolved. Probing their evolution is therefore crucial for investigating possible links to other species of isolated NSs, such as the X-ray dim NSs (XDINS5) and rotating radio transients (RRATs). Here, we investigate the spin evolution of magnetars. Two avenues of evolution are considered: one with exponentially decaying B-fields, the other with sub- and superexponential decay. Using Monte Carlo methods, we synthesize magnetar populations using different input distributions and physical parameters, such as for the initial spin period, its time derivative, and the B-field decay time-scale. Additionally, we introduce a fade-away procedure that can account for the fading of old magnetars, and we briefly discuss the effect of alignment of the B-field and spin axes. Imposing the Galactic core-collapse supernova rate of similar to 20 kyr(-1) as a strict upper limit on the magnetar birthrate and comparing the synthetic populations to the observed one using both manual and automatic optimization algorithms for our input parameter study, we find that the B-field must decay exponentially or superexponentially with a characteristic decay time-scale of 0.5-10 kyr (with a best value of similar to 4 kyr). In addition, the initial spin period must be less than 2 s. If these constraints are kept, we conclude that there are multiple choices of input physics that can reproduce the observed magnetar population reasonably well. We also conclude that magnetars may well be evolutionary linked to the population of XDINSs, whereas they are in general unlikely to evolve into RRATs.

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