Z=50 shell gap near $^{100}$Sn from intermediate-energy Coulomb excitations in even-mass $^{106--112}$Sn isotopes

A.Becerril; A.Brown; A.Chester; A.Gade; A.Schiller; A.Stolz; A.Volya; C.Andreoiu; C.M.Campbell; C.Vaman

arxiv: nucl-ex/0612011 · v1 · submitted 2006-12-08 · ⚛️ nucl-ex

Z=50 shell gap near ¹⁰⁰Sn from intermediate-energy Coulomb excitations in even-mass ¹⁰⁶⁻⁻¹¹²Sn isotopes

C.Vaman , C.Andreoiu , D.Bazin , A.Becerril , A.Brown , C.M.Campbell , A.Chester , J.M.Cook

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D.C.Dinca A.Gade D.Galaviz T.Glasmacher M.Hjorth-Jensen M.Horoi D.Miller V.Moeller W.F.Mueller A.Schiller K.Starosta A.Stolz J.R.Terry A.Volya V. Zelevinsky H.Zwahlen

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keywords shellcoulombintermediate-energyisotopesbeamsbreakingcalculationscontributing

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Rare isotope beams of neutron-deficient $^{106,108,110}$Sn nuclei from the fragmentation of $^{124}$Xe were employed in an intermediate-energy Coulomb excitation experiment yielding $B(E2, 0^+_1 \to 2^+_1)$ transition strengths. The results indicate that these $B(E2,0^+_1 \to 2^+_1)$ values are much larger than predicted by current state-of-the-art shell model calculations. This discrepancy can be explained if protons from within the Z = 50 shell are contributing to the structure of low-energy excited states in this region. Such contributions imply a breaking of the doubly-magic $^{100}$Sn core in the light Sn isotopes.

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Z=50 shell gap near ¹⁰⁰Sn from intermediate-energy Coulomb excitations in even-mass ¹⁰⁶⁻⁻¹¹²Sn isotopes

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