Evidence for the microscopic formation of mixed-symmetry states from magnetic moment measurements

V Werner,P Boutachkov,R B Cakirli,K Aleksandrova,M Evtimova,E A Mccutchan,G Gürdal,B Darakchieva,H Ai,E Williams,A B Garnsworthy,R F Casten,J Qian ,Calina Copos ,G W Anderson ,G Kumbartzki ,M Chamberlain ,N Pietralla ,X Liang ,M Perry ,C Lambie-Hanson ,Stephen Eckel ,R J Casperson ,Peter B Manchev ,Axel Schmidt ,J D Holt ,N Benczer‐Koller ,A Heinz ,C Fitzpatrick ,D A Meyer ,Nicholas J Thompson ,E A Stefanova ,D A Kovacheva ,R Winkler

doi:10.1103/physrevc.78.031301

Abstract

Using the transient field technique, the magnetic moments of the second excited 2+ states in Zr92,94 have been measured for the first time. The large positive g factors, g(22+;92Zr)=+0.76(50) and g(22+;94Zr)=+0.88(27), which are in contrast to the known negative g factors of the 21+ states, are found to be a consequence of weak proton-neutron coupling combined with the Z=40 subshell closure. From their large M1 transition strengths to the 21+ states, in earlier works an assignment to the 22+ states as proton-neutron symmetric and mixed-symmetry states has been made, which are now found to be polarized in their proton-neutron content. This fact allows to identify the underlying microscopic main configurations in the wave functions, which form the building blocks of symmetric and mixed-symmetry states in this region as valence nucleons are added and shell structure changes.Received 31 July 2007DOI:https://doi.org/10.1103/PhysRevC.78.031301©2008 American Physical Society

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