Blaž Bortolato, Jernej F. Kamenik, Michele Tammaro
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Resolution of (Heavy) Primaries in Ultra High Energy Cosmic Rays
Measurements of Ultra-High Energy Cosmic Rays (UHECR) suggest a complex
composition with significant contributions from heavy nuclei at the highest
energies. We systematically explore how the selection and number of primary
nuclei included in the analysis impact the inferred UHECR mass composition.
Introducing a distance measure in the space of $X_{\rm max}$ distribution
moments, we demonstrate that limiting the analysis to a few primaries can
introduce significant biases, particularly as observational data improves. We
provide lists of primaries approximately equidistant in the new measure, which
guaranty unbiased results at given statistical confidence. Additionally, we
explore consistent inclusion of nuclei heavier than iron and up to plutonium,
deriving first observational upper bounds on their contributions to UHECR with
the Pierre Auger Open Data.