Magnetic field decay in neutron stars: from Soft Gamma Repeaters to "weak field magnetars"

Abstract

The recent discovery of the "weak field, old magnetar", the soft gamma repeater SGR 0418+5729, whose dipole magnetic field is less than 7.5 × 1012 G, has raised perplexing questions: How can the neutron star produce SGR-like bursts with such a low magnetic field? What powers the observed X-ray emission when neither the rotational energy nor the magnetic dipole energy are sufficient? These observations, that suggest either a much larger energy reservoir or a much younger true age (or both), have renewed the interest in the evolutionary sequence of magnetars. We examine, here, a phenomenological model for the magnetic field decay: Bdip (Bdip)1+a and compare its predictions with the observed period, P,the period derivative, P, and the X-ray luminosity, LX, of magnetar candidates. We find a strong evidence for a dipole field decay on a timescale of 103 yr for the strongest ( 1015 G) field objects, with a decay index within the range 1 ≤ a < 2 and more likely within 1.5 a 1.8. The decaying field implies a younger age than what is implied by the spinown age. Surprisingly, even with the younger age, the energy released in the dipole field decay is insufficient to power the X-ray emission, suggesting the existence of a stronger internal field, Bint. Examining several models for the internal magnetic field decay we find that it must have a very large (> 1016 G) initial value. Our findings suggest two clear distinct evolutionary tracks -- the SGR/AXP branch and the transient branch, with a possible third branch involving high-field radio pulsars that age into low luminosity X-ray dim isolated neutron stars.