Simulation of Muon-induced Backgrounds for the Colorado Underground Research Institute (CURIE)

Abstract

We present a comprehensive Monte Carlo simulation of muon-induced backgrounds for the Colorado Underground Research Institute (CURIE), a shallow-underground facility with ≈ 415~m.w.e. overburden. Using coupled mute and geant4 frameworks, we characterize the production and transport of muon-induced secondaries through site-specific rock compositions and geometries, establishing a proof-of-concept for high-precision, end-to-end simulations. Our simulations employ angular-dependent muon energy distributions, which improve secondary flux accuracy. For the Subatomic Particle Hideout and Cryolab I research spaces, we predict total muon-induced neutron fluxes of (8.52 1.30sys) × 10-3~m-2s-1 and (8.86 1.62sys) × 10-3~m-2s-1, respectively. Additionally, we develop a Depth-Intensity Relation (DIR) to predict the muon-induced neutron flux as a function of facility depth, which is consistent with measurements across a broad range of underground depths. These results provide quantitative background predictions for experimental design and sensitivity projections at shallow- and deep-underground facilities. They further demonstrate that local geology and overburden geometry influence muon-induced secondary yields and energy spectra, emphasizing the need for site-specific simulations for accurate underground background characterization. Therefore, the simulation framework has been made publicly available at https://doi.org/10.5281/zenodo.17196581https://doi.org/10.5281/zenodo.17196581, for the broader low-background physics community to enable meaningful inter-facility comparisons.

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