Evolutionary Origin of Ultralong-period Radio Transients

Recently, two ultralong-period radio transients, GLEAM-X J162759.5-523504.3 (J1627) and GPM J1839-10 (J1839), were discovered with spin periods longer than 1000 s. The origin of these two ultralong-period radio transients is intriguing in understanding the spin evolution of neutron stars (NSs). In t...

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Bibliographic Details
Published in:The Astrophysical journal 2024-05, Vol.967 (1), p.24
Main Authors: Fan, Yun-Ning, Xu, Kun, Chen, Wen-Cong
Format: Article
Language:English
Subjects:
Disks
Luminosity
Magnetars
Magnetic fields
Neutron stars
Pulsars
Stellar evolution
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Summary:Recently, two ultralong-period radio transients, GLEAM-X J162759.5-523504.3 (J1627) and GPM J1839-10 (J1839), were discovered with spin periods longer than 1000 s. The origin of these two ultralong-period radio transients is intriguing in understanding the spin evolution of neutron stars (NSs). In this work, we examine whether the interaction between strong magnetized NSs and fallback disks can spin NSs down to the observed ultralong period. Our simulations found that the magnetar + fallback disk model can account for the observed period, period derivative, and X-ray luminosity of J1627 in the quasi-spin-equilibrium stage. To evolve to the current state of J1627, the initial mass-accretion rate of the fallback disk and the magnetic field of the NS are in the range of (1.1–30) × 10 24 g s −1 and (2–5) × 10 14 G, respectively. In the active lifetime of the fallback disk, it is impossible for J1839 to achieve the observed upper limit of the period derivative. Therefore, we propose that J1839 may be in the second ejector phase after the fallback disk becomes inactive. Those NSs with a magnetic field of (2–6) × 10 14 G and a fallback disk with an initial mass-accretion rate of ∼10 24 –10 26 g s −1 are possible progenitors of J1839.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ad3aef