Quasiparticle properties of a single impurity in symmetric nuclear matter with a regulated N interaction

Abstract

We explore the quasiparticle properties of a single hyperon propagating through symmetric nuclear matter using the Green's function formalism. The N interaction is described by a non-local regulated low-momentum contact potential with a leading-order constant term and a next-to-leading-order derivative correction. The two coupling constants in the 1S0 and 3S1 channels are fixed by matching the vacuum on-shell T matrix to the scattering length and effective range obtained from modern next-to-next-to-leading-order chiral effective field theory. Using this effective interaction, we calculate the retarded self-energy from the in-medium N ladder T matrix, which sums repeated N scattering in the nucleonic medium. At saturation density, the zero-momentum quasiparticle pole is found at E qp(0, sat)=-29.55~ MeV, in good agreement with the empirical depth of the single potential in nuclear matter. The self-energy decomposition gives a static Born contribution Born(0)=-26.36~ MeV and a dynamical correlation contribution Re\, corr,R(0,E qp)=-3.19~ MeV, showing that repeated in-medium N scattering is needed to reproduce the empirical binding scale. The quasiparticle remains narrow and well defined, with a large residue Z(0)=0.98, a small damping width (0)=0.023~ MeV, and a sharp spectral peak near the quasiparticle energy. At finite momentum, the quasiparticle becomes less bound, with E qp(k, sat) increasing from -29.55~ MeV at k=0 to -6.49~ MeV at k=1~ fm-1, while the residue and width change only weakly. A low-momentum fit gives m*/m=0.747, consistent with the range obtained in Brueckner calculations with Nijmegen hyperon--nucleon potentials.