http://arxiv.org/abs/1806.02017

We performed a complete investigation on the magnetar-like radio pulsar PSR J1119-6127 with the archival high-energy observations obtained after its magnetar-like outbursts in the end July of 2016. The X-ray pulsations can be described by the contribution from two hotspots, and the surface emission from the larger hotspot can be replaced by the magnetized atmospheric radiation. After the bursts, specific regions on the neutron star can be heated up to > 1 keV, and a hard non-thermal component related to the magnetospheric emission can be seen from the spectra in the hard X-ray band. Instead of the cooling down, we find that the thermal emitting region gradually shrunk following the decrease of the source flux after the burst. Marginal hard X-ray pulsations can be detected soon after the outburst, but the signal totally disappeared in a few days. We found that the gamma-ray emission was suppressed during the outburst. This is likely caused by the reconfiguration of the magnetic field of PSR J1119-6127 accompanying with the mode changing in radio pulsation after the burst. Due to the possible global change in the magnetosphere, the timing solution of the pulsar evolved dramatically and the gamma-ray pulsation soon after the these X-ray bursts cannot be resolved without seriously counting the effect of timing noise. Unlike the exponential recovery trend of the spin-down rate that was observed in the 2004 and 2007 glitch events and the glitch events of other pulsars, we did not obtain a similar timing behavior after the glitch of 2016 caused by the bursts. We argue that temporal/spectral behaviors of the observed emission from radio to gamma-ray bands after the burst were caused by a complex combinations of a change of the magnetospheric structure, pair plasma injection and the shrinking emission sites on the neutron star.

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L. Lin, H. Wang, K. Li, et. al.
Thu, 7 Jun 18
21/51

Comments: 12 pages, 10 figures and 5 tables. Submitted to ApJ on May 07