http://arxiv.org/abs/1910.14336
Understanding the evolution of the angle $\chi$ between a magnetar’s rotation and magnetic axes sheds light on the star’s birth properties. This evolution is coupled with that of the stellar rotation $\Omega$, and depends on the competing effects of internal viscous dissipation and external torques. We study this coupled evolution for a model magnetar with a strong internal toroidal field, extending previous work by modelling — for the first time in this context — the strong proto-magnetar wind acting shortly after birth. We also account for the effect of buoyancy forces on viscous dissipation at late times. Typically we find that $\chi\to 90^\circ$ shortly after birth, then decreases towards $0^\circ$ over hundreds of years. From observational indications that magnetars typically have small $\chi$, we infer that these stars are subject to a stronger average exterior torque than radio pulsars, and that they were born spinning faster than $\sim 100$ Hz. Our results allow us to make quantitative predictions for the gravitational and electromagnetic signals from a newborn rotating magnetar.
S. Lander and D. Jones
Fri, 1 Nov 19
50/54
Comments: 9 pages, 6 figures
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