Gravitational Waves from Newborn Accreting Millisecond Magnetars

Abstract

Two accretion columns have been argued to form over the surface of a newborn millisecond magnetar for an extremely high accretion rate 1.8×10-2M\ s-1 that may occur in the core-collapse of a massive star. In this paper, we investigate the characteristics of these accretion columns and their gravitational wave (GW) radiation. For a typical millisecond magnetar (surface magnetic field strength B1015 G and initial spin period P1 ms), we find (1) its accretion columns are cooled via neutrinos and can reach a height 1 km over the stellar surface; (2) its column-induced characteristic GW strain is comparable to the sensitivities of the next generation ground-based GW detectors within a horizon 1 Mpc; (3) the magnetar can survive only a few tens of seconds; (4) during the survival timescale, the height of the accretion columns increases rapidly to the peak and subsequently decreases slowly; (5) the column mass, characteristic GW strain, and maximum GW luminosity have simultaneous peaks in a similar rise-fall evolution. In addition, we find that the magnetar's spin evolution is dominated by the column accretion torque. A possible association with failed supernova is also discussed.