Neutrino-induced hyperon final-state interactions as constraints on the in-medium hyperon potential
Abstract
Hyperon single-particle potentials UY(ρ) control propagation in nuclei and hyperon onset in dense matter, where they soften the neutron-star equation of state and reduce the maximum mass -- the ``hyperon puzzle''. We show that charged-current accelerator (anti)neutrino interactions on 40Ar, producing Λ and Σ inside the nucleus, can constrain these potentials. At SBND and DUNE energies, the trapped-Λ fraction and escaping-hyperon momenta vary monotonically with UΛ and UΣ, with a kaon-vetoed FSI-Σ+ tag adding sensitivity. Inserted in a GM1 relativistic mean-field equation of state at established hypernuclear/Σ-atom depths, the same potentials give M max = 1.94\,M and Λ1.4=1034, below the heaviest pulsars and above the GW170817 bound typical of GM1-class mean fields. A detector-level Fisher forecast yields δUΛ 0.3\,MeV and δUΣ 3-4\,MeV for fixed low-density exponent γ. Since hyperons are produced below saturation, UΛ(ρ0) and γ are 99.8\% anti-correlated; marginalising over γ degrades the anchor to δUΛ 5.6\,MeV (1.3\,MeV with a 0.2 prior), while δUΣ is unchanged. For UΛ, comparable systematics arise from hyperon-nucleon final-state cross sections (-5/+2\,MeV) and the exit-shift/gradient transport prescription (-6\,MeV). For UΣ, the same YN uncertainty biases the fit by O(150)\,MeV; removing the Σ+ tag does not cure this, because the Λ momentum spectrum carries most UΣ information and is itself YN-sensitive. The low-density UΛ anchor is a robust handle, at several-MeV rather than sub-MeV precision. A joint fit with terrestrial and heavy-ion priors gives M max = 2.21+0.04-0.15\,\,Msun, set mainly by the external cΛ prior.
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