Pauli nonlocality and the nucleon effective mass
Abstract
A study of the nucleon mean-field potential in nuclear matter (NM) is done within an extended Hartree-Fock (HF) formalism, using the CDM3Y6 density dependent version of the M3Y interaction which is associated with the nuclear incompressibility K 252 MeV. The momentum dependence of nucleon optical potential (OP) in NM at the saturation density 0 is shown to be due mainly to its exchange term up to k≈ 2 fm-1, so that the Pauli nonlocality is expected to be the main origin of the nucleon effective mass at low momenta. Because nucleons in neutron-rich NM at ≈ 0 are either weakly bound or unbound by the in-medium nucleon-nucleon interaction, the determination of the effective mass of nucleon scattered on targets with neutron excess at low energies should be of interest for the mean-field studies of neutron star matter. For this purpose, the folding model is used to calculate the nonlocal nucleon OP for the optical model analysis of elastic nucleon scattering on 40,48Ca, 90Zr, and 208Pb targets at energies E<50 MeV, to probe the model reliability and validate the WKB local approximation to obtain the local folded nucleon OP. The nucleon effective mass m* is then carefully deduced from the momentum dependence of the local folded nucleon OP which is resulted from the Pauli nonlocality of the exchange term. The neutron-proton effective mass splitting determined at ≈0 from the central strength of the real folded nucleon OP for 48Ca, 90Zr, and 208Pb targets has been found to depend linearly on the neutron-proton asymmetry parameter as m*n-p≈ (0.167 0.018)δ, in a good agreement with the recent empirical constraints.
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