Isospin Symmetry at High Spin Studied via Nucleon Knockout from Isomeric States Article Swipe

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S. A. Milne , M. A. Bentley , E. C. Simpson , T. Baugher , D. Bazin , J. S. Berryman , A. M. Bruce , P. Davies , C. Aa. Diget , A. Gade , T. W. Henry , H. Iwasaki , A. Lemasson , S. M. Lenzi , S. McDaniel , D. R. Napoli , A. Nichols , A. Ratkiewicz , L. Scruton , S. R. Stroberg , J. A. Tostevin , D. Weißhaar , K. Wimmer , R. Winkler ·

YOU? · · 2016 · Open Access · · DOI: https://doi.org/10.1103/physrevlett.117.082502 · OA: W2476311412

One-neutron knockout reactions have been performed on a beam of radioactive ^{53}Co in a high-spin isomeric state. The analysis is shown to yield a highly selective population of high-spin states in an exotic nucleus with a significant cross section, and hence represents a technique that is applicable to the planned new generation of fragmentation-based radioactive beam facilities. Additionally, the relative cross sections among the excited states can be predicted to a high level of accuracy when reliable shell-model input is available. The work has resulted in a new level scheme, up to the 11^{+} band-termination state, of the proton-rich nucleus ^{52}Co (Z=27, N=25). This has in turn enabled a study of mirror energy differences in the A=52 odd-odd mirror nuclei, interpreted in terms of isospin-nonconserving (INC) forces in nuclei. The analysis demonstrates the importance of using a full set of J-dependent INC terms to explain the experimental observations.