Evolutionary implications of a magnetar interpretation for GLEAM-X J162759.5-523504.3

Abstract

The radio pulsar GLEAM-X J162759.5-523504.3 has an extremely long spin period (P = 1091.17\, s), and yet seemingly continues to spin down rapidly (P < 1.2 × 10-9\, ss-1). The magnetic field strength that is implied, if the source is a neutron star undergoing magnetic dipole braking, could exceed 1016\,G. This object may therefore be the most magnetised neutron star observed to date. In this paper, a critical analysis of a magnetar interpretation for the source is provided. (i) A minimum polar magnetic field strength of B 5 × 1015\,G appears to be necessary for the star to activate as a radio pulsar, based on conventional `death valley' assumptions. (ii) Back-extrapolation from magnetic braking and Hall-plastic-Ohm decay suggests that a large angular momentum reservoir was available at birth to support intense field amplification. (iii) The observational absence of X-rays constrains the star's field strength and age, as the competition between heating from field decay and Urca cooling implies a surface luminosity as a function of time. If the object is an isolated, young ( 10\, kyr) magnetar with a present-day field strength of B 1016\,G, the upper limit (≈ 1030\, erg s-1) set on its thermal luminosity suggests it is cooling via a direct Urca mechanism.