Shell effect in A=116--124 Tin isotopes investigated using isotopic analysis of proton scattering at 295 MeV
Abstract
Proton elastic scattering off Sn isotopes at Ep=295 MeV in the mass number range of A=116--124 was investigated using calculation employing relativistic impulse approximation (RIA) with theoretical densities obtained for the Sn isotopes from relativistic Hartree-Bogoliubov (RHB) and nonrelativistic Skyrme Hartree-Fock-Bogoliubov (SHFB) calculations of spherical nuclei. In the RIA calculations, a modified version of the Murdock and Horowitz model that includes a density dependence in the effective nucleon-nucleon (NN) interaction was used. A calculation using the theoretical density obtained from a relativistic calculation employing the DD-ME2 interaction successfully reproduced the experimental data for 122Sn(p,p), but it overestimated the 116Sn(p,p) and 118Sn(p,p) cross sections at backward angles. Isotopic analyses of the (p,p) reactions combined with nuclear structure properties were performed based on reaction calculations that used a model density modified from the DD-ME2 density to optimize the neutron density of the Sn isotopes by fitting the isotopic cross section ratios. The resulting optimized density reproduced the experimental (p,p) data for the series of Sn isotopes from 116Sn to 124Sn. The neutron root-mean-square(rms) radii and the skin thickness of the Sn isotopes obtained in the present analysis exhibited smooth A dependences in the range of A=116--124, which are consistent with the theoretical predictions obtained using the DD-ME2 interaction but seem to contradict the experimental results determined from the (p,p) data. In a detailed analysis of the surface neutron density probed by proton elastic scattering, a signal of the shell effect at N=66 in Sn isotopes was found.
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