Nuclear spin-orbit interaction from chiral pion-nucleon dynamics
Abstract
Using the two-loop approximation of chiral perturbation theory, we calculate the momentum and density dependent nuclear spin-orbit strength Uls(p,kf). This quantity is derived from the spin-dependent part of the interaction energy spin = i 2 σ · ( q × p) Uls(p,kf) of a nucleon scattering off weakly inhomogeneous isospin symmetric nuclear matter. We find that iterated 1π-exchange generates at saturation density, kf0=272.7 MeV, a spin-orbit strength at p=0 of Uls(0,kf0) 35 MeVfm2 in perfect agreement with the empirical value used in the shell model. This novel spin-orbit strength is neither of relativistic nor of short range origin. The potential Vls underlying the empirical spin-orbit strength Uls= Vls rls2 becomes a rather weak one, Vls 17 MeV, after the identification rls= mπ-1 as suggested by the present calculation. We observe however a strong p-dependence of Uls(p,kf0) leading even to a sign change above p=200 MeV. This and other features of the emerging spin-orbit Hamiltonian which go beyond the usual shell model parametrization leave questions about the ultimate relevance of the spin-orbit interaction generated by 2π-exchange for a finite nucleus. We also calculate the complex-valued isovector single-particle potential UI(p,kf)+ i WI(p,kf) in isospin asymmetric nuclear matter proportional to τ3 (N-Z)/(N+Z). For the real part we find reasonable agreement with empirical values and the imaginary part vanishes at the Fermi-surface p=kf.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.