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物理系统在极端的研究ions offers valuable insights into their organization and structure. In nuclear physics, neutron-rich isotopes, especially the light ones with neutron-to-proton ratio significantly different from that of stable nuclei, provide stringent tests of modern nuclear structure theories. These isotopes exist as very short-lived resonances, decaying through spontaneous neutron emission.
Now, in a new study published in available inNature, an international collaboration of researchers led by Yosuke Kondo, an Assistant Professor at the Department of Physics at Tokyo Institute of Technology, reports the first observation of two such isotopes -- oxygen-28 (28O) and oxygen-27 (27O) -- through their decay into oxygen-24 with four and three neutrons, respectively. The nucleus28O, which consists of 8 protons and 20 neutrons (N), is of significant interest as it is expected to be one of the few 'doubly magic' nuclei in the standard shell-model picture of nuclear structure.
The study's success was enabled by the capabilities of the RIKEN RI Beam Factory, which could produce intense beams of unstable nuclei coupled to an active target of thick liquid hydrogen and multi-neutron detection arrays. Proton-induced nucleon knockout reactions from a high-energy29F beam generated the neutron-unbound isotopes27O and28O. The researchers observed these isotopes and studied their properties by directly detecting their decay products.
They found that both27O and28O exist as narrow low-lying resonances and compared their decay energies to the results of sophisticated theoretical models -- a large-scale shell model calculation and a newly developed statistical approach -- based on effective field theories of quantum chromodynamics. Most theoretical approaches predicted higher energies for both isotopes. "Specifically, the statistical coupled-cluster calculations suggested that the energies of27O and28O can provide valuable constraints for the interactions considered in suchab initio方法,“近藤博士指出。
"The researchers also investigated the cross-section for the production of28O from the29F beam, finding it to be consistent with28O not exhibiting a closedN= 20 shell structure. "This result suggests that the 'island of inversion,' whereby the energy gap between neutron orbitals weakens or vanishes, extends beyond the fluorine isotopes28F and29F into the oxygen isotopes," explains Dr. Kondo.
The present findings enhance our understanding of nuclear structure by offering new insights, especially for extremely neutron-rich nuclei. In addition, the detailed investigation of multi-neutron correlations and the study of other exotic systems now become possible with the multi-neutron-decay spectroscopy technique utilized here.
Let us hope that future research unravels many more mysteries surrounding nuclei!
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