http://arxiv.org/abs/1804.06597
The groundbreaking discovery of the optical transient AT2017gfo associated with GW170817 opens a unique opportunity to study the physics of double neutron star mergers. We argue that the standard interpretation of AT2017gfo as being powered by r-process radioactive decay faces the challenge of simultaneously accounting for the peak luminosity and peak time of the event, since it is not easy to achieve the required high mass, and especially the low opacity of the ejecta required to fit the data. A plausible solution would be to invoke an additional energy source, which is probably provided by the merger product. We consider energy injection from two types of the merger products: (1) a post-merger black hole powered by fallback accretion; and (2) a long-lived neutron star (NS) remnant. The former case can only account for the early emission of AT2017gfo, with the late emission still powered by radioactive decay. In the latter case, both early and late emission components can be well interpreted as due to energy injection from a spinning-down NS, with the required mass and opacity of the ejecta components well consistent with known numerical simulation results. We suggest that there is a strong indication that the merger product of GW170817 is a long-lived (supra-massive or even permanently stable), low magnetic field NS. The result provides a stringent constraint on the equations of state of NSs.
S. Li, L. Liu, Y. Yu, et. al.
Thu, 19 Apr 18
37/47
Comments: 8 pages, 3 figures, 1 table; submitted to ApJL