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Radioactive decay of specific heavy elements as an energy source for late-time kilonovae and potential <i>James Webb Space Telescope</i> observations

Meng-Hua Chen, En‐Wei Liang

2023Monthly Notices of the Royal Astronomical Society12 citationsDOIOpen Access PDF

Abstract

ABSTRACT Revealing the temporal evolution of individual heavy elements synthesized in the merger ejecta from binary neutron star mergers not only improves our understanding of the origin of heavy elements beyond iron but also clarifies the energy sources of kilonovae. In this work, we present a comprehensive analysis of the temporal evolution of the energy fraction of each nuclide based on r-process nucleosynthesis simulations. The heavy elements dominating the kilonova emission within ∼100 days are identified, including 127Sb, 128Sb, 129Sb, 130Sb, 129Te, 132I, 222Rn, 223Ra, 224Ra, and 225Ac. It is found that the late-time kilonova light curve (t ≳ 20 days) is highly sensitive to the presence of the heavy element 225Ac (with a half-life of 10.0 days). Our analysis shows that the James Webb Space Telescope (JWST), with its high sensitivity in the near-infrared band, is a powerful instrument for the identification of these specific heavy elements.

Topics & Concepts

KilonovaPhysicsEjectaNucleosynthesisAstrophysicsNuclider-processNeutron starAstronomySpitzer Space TelescopeRadioactive decayTelescopeLight curveNuclear physicsSupernovaGamma-ray bursts and supernovaePulsars and Gravitational Waves ResearchNuclear physics research studies
Radioactive decay of specific heavy elements as an energy source for late-time kilonovae and potential <i>James Webb Space Telescope</i> observations | Litcius