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How Robust is the N=34 Subshell Closure? First Spectroscopy of ^{52}Ar.

H N Liu1,2,3, A Obertelli1,2,4, P Doornenbal4

  • 1Département de Physique Nucléaire, IRFU, CEA, Université Paris-Saclay, F-91191 Gif-sur-Yvette, France.

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Summary
This summary is machine-generated.

The first gamma-ray spectroscopy of Argon-52 (52Ar) reveals a persistent N=34 subshell closure, challenging previous nuclear structure assumptions. This finding provides crucial insights into the island of inversion and nuclear stability.

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Area of Science:

  • Nuclear Physics
  • Nuclear Spectroscopy
  • Exotic Nuclei

Background:

  • Understanding nuclear shell structure is fundamental to nuclear physics.
  • The N=34 neutron shell closure is known in the doubly magic ^{54}Ca, but its persistence in neutron-rich isotopes is less understood.
  • Investigating neutron-rich Argon (Ar) isotopes provides insights into nuclear forces and shell evolution.

Purpose of the Study:

  • To perform the first gamma-ray spectroscopy of the neutron-rich isotope ^{52}Ar.
  • To investigate the persistence of the N=34 neutron shell closure in ^{52}Ar.
  • To explore the evolution of nuclear structure in neutron-rich Ar isotopes.

Main Methods:

  • Utilized the ^{53}K(p,2p) one-proton removal reaction at approximately 210 MeV/u.
  • Employed gamma-ray spectroscopy to detect emitted photons.
  • Conducted shell-model calculations using phenomenological and chiral effective field theory interactions.

Main Results:

  • Measured the 2_{1}^{+} excitation energy of ^{52}Ar to be 1656(18) keV.
  • This excitation energy is the highest observed among Ar isotopes with N>20.
  • Experimental data and theoretical calculations support the existence of an N=34 subshell closure in ^{52}Ar.

Conclusions:

  • The results provide the first experimental evidence for the N=34 subshell closure persisting beyond ^{54}Ca, even below the magic proton number Z=20.
  • The findings challenge traditional nuclear shell models and highlight the complex evolution of shell structure in exotic nuclei.
  • Shell-model calculations successfully reproduce the observed systematics, reinforcing the N=34 subshell closure in ^{52}Ar.