The impact of nuclear shape on the emergence of the neutron dripline

Atomic nuclei are composed of a certain number of protons Z and neutrons N . A natural question is how large Z and N can be. The study of superheavy elements explores the large Z limit 1 , 2 , and we are still looking for a comprehensive theoretical explanation of the largest possible N for a given...

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Bibliographic Details
Published in:Nature (London) 2020-11, Vol.587 (7832), p.66-71
Main Authors: Tsunoda, Naofumi, Otsuka, Takaharu, Takayanagi, Kazuo, Shimizu, Noritaka, Suzuki, Toshio, Utsuno, Yutaka, Yoshida, Sota, Ueno, Hideki
Format: Article
Language:English
Subjects:
639/766/387/1126
639/766/387/1129
Atomic properties
Deformation effects
Eigenvalues
Energy
Experiments
Fluorine
Humanities and Social Sciences
Isotopes
Magnesium
multidisciplinary
Neutrons
Nuclear fusion
Nuclear physics
Nuclei
Nuclei (nuclear physics)
Nucleons
Oxygen
Protons
Science
Science (multidisciplinary)
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Summary:Atomic nuclei are composed of a certain number of protons Z and neutrons N . A natural question is how large Z and N can be. The study of superheavy elements explores the large Z limit 1 , 2 , and we are still looking for a comprehensive theoretical explanation of the largest possible N for a given Z —the existence limit for the neutron-rich isotopes of a given atomic species, known as the neutron dripline 3 . The neutron dripline of oxygen ( Z  = 8) can be understood theoretically as the result of single nucleons filling single-particle orbits confined by a mean potential, and experiments confirm this interpretation. However, recent experiments on heavier elements are at odds with this description. Here we show that the neutron dripline from fluorine ( Z  = 9) to magnesium ( Z  = 12) can be predicted using a mechanism that goes beyond the single-particle picture: as the number of neutrons increases, the nuclear shape assumes an increasingly ellipsoidal deformation, leading to a higher binding energy. The saturation of this effect (when the nucleus cannot be further deformed) yields the neutron dripline: beyond this maximum N , the isotope is unbound and further neutrons ‘drip’ out when added. Our calculations are based on a recently developed effective nucleon–nucleon interaction 4 , for which large-scale eigenvalue problems are solved using configuration-interaction simulations. The results obtained show good agreement with experiments, even for excitation energies of low-lying states, up to the nucleus of magnesium-40 (which has 28 neutrons). The proposed mechanism for the formation of the neutron dripline has the potential to stimulate further thinking in the field towards explaining nucleosynthesis with neutron-rich nuclei. A mechanistic explanation for the origin of the neutron dripline shows that nuclei accommodate the addition of neutrons by becoming increasingly ellipsoidal, up to a maximum number of neutrons, reconciling theory and experiments.
ISSN:0028-0836
1476-4687
DOI:10.1038/s41586-020-2848-x