Abstract
High-energy cosmic rays are observed indirectly by detecting the extensive air showers initiated in Earth’s atmosphere. The interpretation of these observations relies on accurate models of air shower physics, which is a challenge and an opportunity to test QCD under extreme conditions. Air showers are hadronic cascades, which give rise to a muon component through hadron decays. The muon number is a key observable to infer the mass composition of cosmic rays. Air shower simulations with state-of-the-art QCD models show a significant muon deficit with respect to measurements; this is called the Muon Puzzle. By eliminating other possibilities, we conclude that the most plausible cause for the muon discrepancy is a deviation in the composition of secondary particles produced in high-energy hadronic interactions from current model predictions. The muon discrepancy starts at the TeV scale, which suggests that this deviation is observable at the Large Hadron Collider. An enhancement of strangeness production has been observed at the LHC in high-density events, which can potentially explain the puzzle, but the impact of the effect on forward produced hadrons needs further study, in particular with future data from oxygen beam collisions.
Highlights
Cosmic rays are fully-ionised nuclei with relativistic kinetic energies that arrive at Earth
The Muon Puzzle refers to a deficit in GeV muons that are produced near the end of the hadronic cascade in a simulated air shower
The shower-to-shower fluctuations of the muon number Nμ are sensitive to the first interactions in the hadronic cascade and to the cosmic-ray mass composition (Fukui et al 1960; Cazon et al 2018)
Summary
Cosmic rays are fully-ionised nuclei with relativistic kinetic energies that arrive at Earth. Cosmic rays originate from unknown sources outside of our solar system and are messengers of the high-energy universe. It spans over 11 orders in energy and over more than 30 orders in flux intensity, which can only be covered by multiple experiments using different measurement techniques. The particle with the highest energy ever reported was a cosmic ray (Bird et al 1995a) with (320 ± 90) EeV = (3.2 ± 0.9) · 1011 GeV (1 EeV = 109 GeV). Ultra-high energy cosmic rays with energies exceeding EeV are of unknown extra-galactic origin
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