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Search for in-band transitions in the candidate superdeformed band in Si 28

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Author(s)

  • M. N. Harakeh
  • J. Isaak
  • N. Kobayashi
  • A. Tamii
  • S. Adachi
  • P. Adsley
  • N. Aoi
  • A. Bracco
  • A. Brown
  • M. P. Carpenter
  • J. J. Carroll
  • S. Courtin
  • F. C.L. Crespi
  • G. Fruet
  • Y. D. Fang
  • H. Fujita
  • G. Gey
  • T. H. Hoang
  • N. Ichige
  • E. Ideguchi
  • A. Inoue
  • C. Iwamoto
  • T. Koike
  • M. Kumar Raju
  • M. L. Liu
  • D. Montanari
  • P. Von Neumann-Cosel
  • S. Noji
  • H. J. Ong
  • D. Savran
  • J. M. Schmitt
  • C. Sullivan
  • B. Wasilewska
  • M. Weinert
  • V. Werner
  • Y. Yamamoto
  • R. G.T. Zegers
  • X. H. Zhou
  • S. Zhu

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Publication details

JournalPhysical Review C
DateAccepted/In press - 15 Nov 2021
DatePublished (current) - 30 Nov 2021
Issue number5
Volume104
Original languageEnglish

Abstract

Background: Superdeformed (SD) bands are suggested by theory around Ca40 and in lighter alpha-conjugate nuclei such as Mg24, Si28, and S32. Such predictions originate from a number of theoretical models including mean-field models and antisymmetrized molecular dynamics (AMD) calculations. While SD bands have been identified in Ca40 and its near neighbors, evidence of their existence in the lighter, midshell nuclei is circumstantial at best. The key evidence of superdeformation would be the observation of transitions with high B(E2) transition strengths connecting states in a rotational sequence. This is challenging information to obtain since the bands lie at a high excitation energy and competition from out-of-band decay is dominant. Purpose: The purpose of the present study is to establish a new methodology to circumvent the difficulties in identifying and quantifying in-band transitions through directly populating candidate states in the SD band in Si28 through inelastic alpha scattering, selecting such states with a spectrometer, and measuring their gamma-ray decay with a large array of high-purity germanium detectors, allowing direct access to electromagnetic transition strengths. Methods: Excited states in Si28 were populated in the Si28(α,α′) reaction using a 130-MeV He4 beam from the K140 AVF cyclotron at the Research Center for Nuclear Physics. Outgoing alpha particles were analyzed using the Grand Raiden spectrometer positioned at an angle of 9.1° to favor the population of states with J≈4. Coincident gamma rays were detected with the CAGRA array of 12 HPGe clover detectors augmented by a set of four large LaBr3 detectors. Results: Data analysis showed that it was possible to identify additional low-energy transitions in competition with high-energy decays from excited states in Si28 in the vicinity of 10 MeV. However, while the candidate 4+ SD state at 10.944 MeV was populated, a 1148-keV transition to the candidate 2+ SD state at 9.796 MeV was not observed, and only an upper limit for its transition strength of B(E2)<43 W.u. could be established. This contradicts AMD predictions of ≈200 W.u. for such a transition. Conclusion: The present study strongly rejects the hypothesis that the candidate set of states identified in Si28 represents an SD band, which demonstrates the potential of the methodology devised here.

Bibliographical note

Funding Information:
This work was supported by the International Joint Research Promotion Program of Osaka University and by the Deutsche Forschungsgemeinschaft (DFG) under Grant No. SFB 1245, project ID 279384907. The Nuclear Data Review Group from the National Nuclear Data Center, Brookhaven National Laboratory, is acknowledged for their advice on handling the presentation of limits and their extraction using Monte Carlo techniques for variables with large uncertainties.

Publisher Copyright:
© 2021 American Physical Society.

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