Evolution of Nuclear Shell Structure due to the Pion Exchange Potential
arXiv:nucl-th/0609076 · doi:10.1209/0295-5075/82/12001
Abstract
The evolution of nuclear shell structure is investigated for the first time within density-dependent relativistic Hartree-Fock theory and the role of $Ï$-exchange potential is studied in detail. The energy differences between the neutron orbits $\Lrb{\nu1h_{9/2},ν1i_{13/2}}$ in the N=82 isotones and between the proton ones $\Lrb{\pi1g_{7/2},\pi1h_{11/2}}$ in the Z=50 isotopes are extracted as a function of neutron excess $N-Z$. A kink around $Z = 58$ for the N=82 isotones is found as an effect resulting from pion correlations. It is shown that the inclusion of $Ï$-coupling plays a central role to provide realistic isospin dependence of the energy differences. In particular, the tensor part of the $Ï$-coupling has an important effect on the characteristic isospin dependence observed in recent experiments.
4 pages and 4 figures