Nuclear energy density functional from chiral pion-nucleon dynamics revisited
arXiv:0912.3207 · doi:10.1016/j.nuclphysa.2010.02.004
Abstract
We use a recently improved density-matrix expansion to calculate the nuclear energy density functional in the framework of in-medium chiral perturbation theory. Our calculation treats systematically the effects from $1Ï$-exchange, iterated $1Ï$-exchange, and irreducible $2Ï$-exchange with intermediate $Î$-isobar excitations, including Pauli-blocking corrections up to three-loop order. We find that the effective nucleon mass $M^*(Ï)$ entering the energy density functional is identical to the one of Fermi-liquid theory when employing the improved density-matrix expansion. The strength $F_\nabla(Ï)$ of the $(\vec\nabla Ï)^2$ surface-term as provided by the pion-exchange dynamics is in good agreement with that of phenomenological Skyrme forces in the density region $Ï_0/2 <Ï<Ï_0$. The spin-orbit coupling strength $F_{so}(Ï)$ receives contributions from iterated $1Ï$-exchange (of the ``wrong sign'') and from three-nucleon interactions mediated by $2Ï$-exchange with virtual $Î$-excitation (of the ``correct sign''). In the region around $Ï_0/2 \simeq 0.08 $fm$^{-3}$ where the spin-orbit interaction in nuclei gains most of its weight these two components tend to cancel, thus leaving all room for the short-range spin-orbit interaction. The strength function $F_J(Ï)$ multiplying the square of the spin-orbit density comes out much larger than in phenomenological Skyrme forces and it has a pronounced density dependence.
18 pages, 7 figures, submitted to Nuclear Physics A