Gamma-Ray Emission Produced by r-process Elements from Neutron Star Mergers

Abstract

The observation of a radioactively powered kilonova AT~2017gfo associated with the gravitational wave-event GW170817 from binary neutron star merger proves that these events are ideal sites for the production of heavy r-process elements. The gamma-ray photons produced by the radioactive decay of heavy elements are unique probes for the detailed nuclide compositions. Basing on the detailed r-process nucleosynthesis calculations and considering radiative transport calculations for the gamma-rays in different shells, we study the gamma-ray emission in a merger ejecta on a timescale of a few days. It is found that the total gamma-ray energy generation rate evolution is roughly depicted as E t-1.3. For the dynamical ejecta with a low electron fraction (Y e0.20), the dominant contributors of gamma-ray energy are the nuclides around the second r-process peak (A130), and the decay chain of 132Te (t1/2=3.21~days) → 132I (t1/2=0.10~days) → 132Xe produces gamma-ray lines at 228 keV, 668 keV, and 773 keV. For the case of a wind ejecta with Y e0.30, the dominant contributors of gamma-ray energy are the nuclides around the first r-process peak (A80), and the decay chain of 72Zn (t1/2=1.93~days) → 72Ga (t1/2=0.59~days) → 72Ge produces gamma-ray lines at 145 keV, 834 keV, 2202 keV, and 2508 keV. The peak fluxes of these lines are 10-9 10-7~ph~cm-2 s-1, which are marginally detectable with the next-generation MeV gamma-ray detector ETCC if the source is at a distance of 40~Mpc.