Atmospheric & geodesic controls on muon rate: a numerical study based on Corsika

TL;DR

This study uses CORSIKA simulations to analyze how atmospheric and geodesic factors influence muon flux, aiming to improve the accuracy of muography models under varying environmental conditions.

Contribution

The paper provides a detailed numerical analysis of environmental effects on muon flux using CORSIKA, highlighting their importance for precise muography modeling.

Findings

Environmental conditions significantly affect muon flux predictions.

Monte Carlo simulations can accurately model atmospheric impacts.

Results improve understanding of muon behavior near the horizon.

Abstract

Muon rate models play a key role in converting measured data into information on the density distributions of a target. Any given muography measurement, either in transmission or in scattering mode, requires a proper modelization of the muon flux according to the localization and to the atmospheric conditions. Two approaches are commonly used: either through semi-empirical models calibrated on existing data or via Monte-Carlo simulations. The former requires extrapolations to the field experiment conditions while the latter offers the advantage of tackling down in an unique way all relevant parameters such as barometric conditions, geomagnetic field, atmosphere density etc. Although significant progress were made in the last decades, precision muography experiments require more and more accuracy on the models, especially for the muons close to the horizon where large disparities still remain. In this paper we present detailed results obtained with the CORSIKA simulation framework to emphasize and quantify the impact of the environmental conditions on the sensitivity of muography measurements.