Probing Circumstellar Material and Shock Acceleration in Core-Collapse Supernovae with High-Energy Neutrinos

Abstract

We study high-energy (HE) neutrino production from interactions between supernova (SN) ejecta and the surrounding circumstellar material (CSM), focusing on regular Type~II and Type~IIn SNe. Using observationally inferred CSM density distributions, we calculate the resulting neutrino fluxes and examine their dependence on key parameters, including the CSM density normalization D*, outer radius R csm, proton acceleration efficiency εp, and magnetic energy fraction εB. Detection prospects are assessed with a binned likelihood analysis for IceCube, indicating that nearby SNe with moderately dense, confined CSM can produce detectable signals, with a typical detection horizon of 0.1 - 1 Mpc. For a Galactic SN at 10 kpc, high-statistics neutrino data with detailed temporal and spectral information can constrain D*, R csm, and εp to within a factor of 10 or to a precision of 20\%, depending on the assumed values of D* and R csm. These neutrino signals thus provide a complementary probe of the CSM profile and shock acceleration, alongside traditional electromagnetic observations.