Uncertainties in Kilonova Heating from Nuclear Physics Inputs

The rapid neutron capture process (r-process) is one of the main mechanisms whereby elements heavier than iron are synthesized, and is responsible for the creation of the heaviest stable isotopes of the actinides. Observations of the gravitational wave event GW170817, and its optical counterpart, AT2017gfo, support neutron star mergers as an r-process production site. Efforts to accurately and reliably model yields and observational signatures from these sites require inputs from nuclear physics, which introduce potentially large uncertainties. We use nucleosynthesis modeling to evaluate the role of these inputs, including different nuclear mass models, fission decay rates, and daughter product distributions in lanthanide and actinide production. I will show that applying different nuclear physics inputs generates discrepancies in abundances of key isotopes which contribute significantly to the overall nuclear energy generation in the merger event, which is a necessary component of kilonova lightcurve modelling.