D-term of nuclei exhibits kinks at magic neutron numbers, showing strong sensitivity of mechanical properties to shell structure.
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First lifetime measurement of the 0_3+ state in 118Sn yields an enhanced E0 transition of 150(30) milliunits, indicating multiple shape coexistence, with supporting calculations showing three shapes in 116-120Sn.
Δl=1 and Δl=3 couplings act synergistically to drive octupole deformation, requiring a revised paradigm for reflection asymmetry in nuclei.
Octupole correlations within the IBM-DFT framework generate low-energy 0+ states that account for the abrupt changes in two-neutron transfer intensities at N≈88-90 in rare-earth nuclei.
citing papers explorer
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Mass radius and D-term of atomic nuclei in relativistic mean field theory
D-term of nuclei exhibits kinks at magic neutron numbers, showing strong sensitivity of mechanical properties to shell structure.
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Multiple shape coexistence near Sn118: First 03+ lifetime measurement
First lifetime measurement of the 0_3+ state in 118Sn yields an enhanced E0 transition of 150(30) milliunits, indicating multiple shape coexistence, with supporting calculations showing three shapes in 116-120Sn.
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$\Delta l =1$ coupling of single-particle orbitals in octupole deformed nuclei
Δl=1 and Δl=3 couplings act synergistically to drive octupole deformation, requiring a revised paradigm for reflection asymmetry in nuclei.
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Octupole correlation effects on two-neutron transfer intensity in rare-earth nuclei
Octupole correlations within the IBM-DFT framework generate low-energy 0+ states that account for the abrupt changes in two-neutron transfer intensities at N≈88-90 in rare-earth nuclei.