Isovector giant dipole resonances in proton-rich Ar and Ca isotopes

The isovector giant dipole resonances (IVGDR) in proton-rich Ar and Ca isotopes have been systematically investigated using the resonant continuum Hartree-Fock+BCS (HF+BCS) and quasiparticle random phase approximation (QRPA) methods. The Skyrme SLy5 and density -dependent contact pairing interactions are employed in the calculations. In addition to the giant dipole resonances at energy around 18 MeV, pygmy dipole resonances (PDR) are found to be located in the energy region below 12 MeV. The calculated energy -weighted moments of PDR in nuclei close to the proton drip-line exhaust about 4% of the TRK sum rule. The strengths decrease with increasing mass number in each isotopic chain. The transition densities of the PDR states show that motions of protons and neutrons are in phase in the interiors of nuclei, while the protons give the main contribution at the surface. By analyzing the QRPA amplitudes of proton and neutron 2-quasiparticle configurations for a given low-lying state, we find that only a few proton configurations give significant contributions. They contribute about 95% to the total QRPA amplitudes, which indicates that the collectivity of PDR states is not strong in proton-rich nuclei in the present study.

Automated summary

The study investigates the isovector giant dipole resonances in proton-rich Ar and Ca isotopes, revealing both giant resonances at around 18 MeV and pygmy resonances below 12 MeV. The strength of PDR decreases with increasing mass number, with proton motions dominating at the surface of nuclei. The collectivity of PDR states is found to be weak in proton-rich nuclei based on the analysis of QRPA amplitudes.