Theoretical modeling of charged current μ(μ)-40Ar DIS at DUNE energies

Abstract

The charged current μ(μ)-induced deep inelastic scattering (DIS) from an 40Ar target is studied using a microscopic framework that incorporates nuclear medium effects due to Fermi motion, binding energy, nucleon correlations, mesonic (π and ) contributions, and nuclear shadowing and antishadowing across the relevant Bjorken-x region. The nuclear structure functions FiA(x,Q2) (i=1-3) are evaluated using a relativistic nucleon spectral function (Sh) within the local density approximation employing the free nucleon structure functions, FiN(x,Q2) (i=1-3). These FiN(x,Q2) (i=1-3) are calculated using parton distribution functions (PDFs) from MMHT 2014 parameterization, including higher-order perturbative QCD corrections up to next-to-next-to-leading order (NNLO), along with nonperturbative target mass corrections (TMC). The resulting nuclear structure functions FiA(x,Q2) (i=1-3) are subsequently used to compute the differential DIS cross sections for 40Ar nucleus. Numerical results are presented for μ(μ) beam energies E=4 GeV and E=6 GeV for the differential scattering cross sections d2σdx dy and dσdx, relevant to ongoing and upcoming liquid-argon neutrino experiments such as DUNE and the Fermilab Short-Baseline Neutrino program.