Type: Article
Publication Date: 2022-08-24
Citations: 24
DOI: https://doi.org/10.1103/physrevd.106.043023
We present simulations of the development of high-energy cosmic-ray air showers penetrating high-altitude ice layers that can be found at the polar regions. We use a combination of the corsika Monte Carlo code and the geant4 simulation toolkit, and focus on the particle cascade that develops in the ice to describe its most prominent features. We discuss the impact of the ice layer on the total number of particles in function of depth of the air shower, and we give a general parametrization of the charge distribution in the cascade front in function of ${X}_{\mathrm{max}}$ of the cosmic ray air shower, which can be used for analytical and semianalytical calculations of the expected Askaryan radio emission of the in-ice particle cascade. We show that the core of the cosmic ray air shower dominates during the propagation in ice, therefore creating an in-ice particle cascade strongly resembling a neutrino-induced particle cascade. Finally, we present the results of simulations of the Askaryan radio emission of the in-ice particle cascade, showing that the emission is dominated by the shower core, and discuss the feasibility of detecting the plasma created by the particle cascade in the ice using RADAR echo techniques.