Impact of octupole deformation on the nuclear electromagnetic response
Abstract
Background: Properties of giant dipole resonances, along with other nuclear resonances, provide valuable tools for refining theoretical models as they reflect collective features of nuclear matter. Among such collective phenomena is octupole deformation, whose impact on resonance features, however, is less studied. Purpose: Investigate the effect of reflection-symmetry-breaking octupole deformation on electric and magnetic transition strengths in atomic nuclei. Methods: Calculations were performed using linear response theory with the iterative finite amplitude method to solve quasiparticle random phase approximation-type equations. Underlying ground-state solutions were obtained within the framework of axially symmetric Skyrme-Hartree-Fock-Bogoliubov (HFB) using three different Skyrme functionals. Results: Electric and magnetic multipole responses were calculated for octupole-deformed even-even Rn, Ra, Th, U, Pu, and Cm isotopes. Calculations were performed on top of two distinct deformed ground-state solutions: one constrained to conserve parity, and the other allowing parity breaking. Sum rules were calculated from M1 transition strengths and compared with the expected correlations to certain ground-state properties. Conclusions: Based on our results, the octupole deformation has only a modest effect on the transition strengths in the resonances. In turn, M1 transition strengths have a greater effect at lower energies (0\,--\,8\,MeV), which encourages further investigation. Isoscalar E3 transition strength was confirmed to have a significant contribution from the rotational Nambu--Goldstone mode in the parity-breaking HFB solution, and thus, removing it was found necessary.
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