Bursts from High-magnetic-field Pulsars Swift J1818.0-1607 and PSR J1846.4-0258

The detection of magnetar-like bursts from highly magnetic ( B > 10 13 G) rotation-powered pulsars (RPPs) opened the magnetar population to yet another group of neutron stars. At the same time the question arose as to whether magnetar-like bursts from high-B RPPs have similar characteristics to b...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 942; no. 1; pp. 8 - 21
Main Authors: Uzuner, Mete, Keskin, Özge, Kaneko, Yuki, Göğüş, Ersin, Roberts, Oliver J., Lin, Lin, Baring, Matthew G., Güngör, Can, Kouveliotou, Chryssa, van der Horst, Alexander J., Younes, George
Format: Journal Article
Language:English
Published: Philadelphia The American Astronomical Society 01-01-2023
IOP Publishing
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Summary:The detection of magnetar-like bursts from highly magnetic ( B > 10 13 G) rotation-powered pulsars (RPPs) opened the magnetar population to yet another group of neutron stars. At the same time the question arose as to whether magnetar-like bursts from high-B RPPs have similar characteristics to bursts from known magnetar sources. We present here our analyses of the Fermi Gamma-ray Burst Monitor (GBM) data from two magnetar candidates, Swift J1818.0−1607 (a radio-loud magnetar) and PSR J1846.4−0258. Both sources entered active bursting episodes in 2020 triggering Fermi-GBM in 2020 and in early 2021. We searched for untriggered bursts from both sources and performed temporal and spectral analyses on all events. Here, we present the results of our comprehensive burst search and analyses. We identified 37 and 58 bursts that likely originated from Swift J1818.0−1607 and PSR J1846.4−0258, respectively. We find that the bursts from these sources are shorter on average than typical magnetar bursts. In addition, their spectra are best described with a single blackbody function with kT ∼ 10–11 keV; several relatively bright events, however, show higher energy emission that could be modeled with a cutoff power-law model. We find that the correlation between the blackbody emitting area and the spectral temperature for the burst ensemble of each pulsar deviates from the ideal Stefan–Boltzmann law, as it does for some burst-active magnetars. We interpret this characteristic as being due to the significant radiation anisotropy expected from optically thick plasmas in very strong magnetic fields.
Bibliography:High-Energy Phenomena and Fundamental Physics
AAS41671
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aca482