We investigate the observed muon deficit in air shower simulations when compared to ultrahigh-energy cosmic ray (UHECR) data. Based upon the observed enhancement of strangeness production in high- energy hadronic collisions reported by the ALICE Collaboration, the concomitant pi ↔ K swap is considered as the keystone to resolve the muon anomaly through its corresponding impact on the shower development. We construct a toy model in terms of the pi ↔ K swapping probability F$_s$. We present a parametrization of F$_s$ in terms of the pseudorapidity that can accommodate the UHECR data. Looking to the future, we explore potential strategies for model improvement using the massive amounts of data to be collected by LHC neutrino detectors, such as FASERnu and experiments at the Forward Physics Facility. We calculate the corresponding sensitivity to F$_s$ and show that these experiments will be able to probe the model phase space.
We investigate the observed muon deficit in air shower simulations when compared to ultrahigh-energy cosmic ray (UHECR) data. Based upon the observed enhancement of strangeness production in high-energy hadronic collisions reported by the ALICE Collaboration, the concomitant π↔K swap is considered as the keystone to resolve the muon anomaly through its corresponding impact on the shower development. We construct a toy model in terms of the π↔K swapping probability Fs. We present a parametrization of Fs in terms of the pseudorapidity that can accommodate the UHECR data. Looking to the future, we explore potential strategies for model improvement using the massive amounts of data to be collected by LHC neutrino detectors, such as FASERν and experiments at the Forward Physics Facility. We calculate the corresponding sensitivity to Fs and show that these experiments will be able to probe the model phase space.