Probing the single-particle character of rotational states in ¹⁹F using a short-lived isomeric beam

D. Santiago-Gonzalez (1 , 2) , K. Auranen (2) , M. L. Avila (2) , A. D. Ayangeakaa (2) , B. B. Back (2) , S. Bottoni (2) , M. P. Carpenter (2)

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J. Chen (2) C. M. Deibel (1) A. A. Hood (1) C. R. Hoffman (2) R. V. F. Janssens (2) C. L. Jiang (2) B. P. Kay (2) S. A. Kuvin (3) A. Lauer (1) J. P. Schiffer (2) J. Sethi (4 R. Talwar (2) I. Wiedenhoever (5) J. Winkelbauer (6) S. Zhu (2) ((1) Department of Physics Astronomy Louisiana State University USA (2) Physics Division Argonne National Laboratory (3) Department of Physics University of Connecticut (4) Department of Chemistry Biochemistry University of Maryland (5) Department of Physics Florida State University (6) Los Alamos National Laboratory USA)

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classification ⚛️ nucl-ex

keywords single-particlestatebeamisomericrotationalagreementatomicband

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A beam containing a substantial component of both the $J^{\pi}=5^+$, $T_{1/2}=162$ ns isomeric state of $^{18}$F and its $1^+$, 109.77-min ground state has been utilized to study members of the ground-state rotational band in $^{19}$F through the neutron transfer reaction $(d$,$p)$ in inverse kinematics. The resulting spectroscopic strengths confirm the single-particle nature of the 13/2$^+$ band-terminating state. The agreement between shell-model calculations, using an interaction constructed within the $sd$ shell, and our experimental results reinforces the idea of a single-particle/collective duality in the descriptions of the structure of atomic nuclei.

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Probing the single-particle character of rotational states in ¹⁹F using a short-lived isomeric beam

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