Researchers at the Institute of Modern Physics and collaborators have discovered two new isotopes, osmium-160 and tungsten-156, revealing potential for lead-164 to be a stable, doubly magic nucleus. This breakthrough enhances the understanding of nuclear stability and challenges traditional views on magic numbers, indicating a significant step forward in nuclear physics.
Scientists at the Institute of Modern Physics (IMP) under the Chinese Academy of Sciences (CAS), along with their collaborators, have created two novel isotopes—osmium-160 and tungsten-156. This discovery provides new insights into the architecture of atomic nuclei and suggests that lead-164 might possess enhanced stability as a potentially doubly magic nucleus.
The study was published in Physical Review Letters and highlighted as an Editors’ Suggestion.
“Magic numbers” of protons and neutrons can make an atomic nucleus particularly stable. The traditional magic numbers are 8, 20, 28, 50, 82 and 126. In previous studies, researchers discovered the vanishing of traditional magic numbers and the emergence of new magic numbers on the neutron-rich side of the nuclide chart.
Will other traditional magic numbers disappear in extremely neutron-deficient nuclear regions? Further exploration is of great significance to enrich and develop nuclear theories and to deepen our understanding of nuclear forces.
Experimental Achievements and Findings
In this study, researchers carried out the experiment at the gas-filled recoil separator-Spectrometer for Heavy Atoms and Nuclear Structure (SHANS), which is located at the Heavy Ion Research Facility in Lanzhou, China.
Using the fusion evaporation reaction, researchers synthesized osmium-160 and tungsten-156 for the first time. They measured the α-particle energy and the half-life of osmium-160, which is an α-emitting isotope. Meanwhile, they determined that the daughter nucleus, tungsten-156, is a β+ emitter with a half-life of 291 ms.
With the newly measured α-decay data, researchers derived the α-decay reduced width for osmium-160 and compared it with other nuclei with 84 neutrons but fewer protons. They found a surprising trend: The higher the proton number, the lower the decay rate.
Implications for Nuclear Theory and Stability
“This trend is interpreted as evidence for the strengthening of 82-neutron shell closure towards the proton drip line, which is supported by the increase of the neutron-shell gaps predicted in theoretical models,” said Dr. Yang Huabin from IMP, the first author of the paper.
Moreover, researchers suggested that the enhanced stability of 82-neutron shell closure can be attributed to the increasing closeness to the doubly magic nucleus lead-164, which might be a stable nucleus with 82 protons and 82 neutrons. Although lead-164 is predicted beyond the proton-drip line, the enhanced shell effect has the potential to make it a bound or quasi-bound nucleus.
Reference: “Discovery of New Isotopes 160Os and 156W: Revealing Enhanced Stability of the N=82 Shell Closure on the Neutron-Deficient Side” by 15 February 2024, Physical Review Letters.
DOI: 10.1103/PhysRevLett.132.072502
The study was conducted in collaboration with the University of Chinese Academy of Sciences, the Advanced Energy Science and Technology Guangdong Laboratory, Shandong University, Sun Yat-sen University, Guangxi Normal University, Tongji University, and the Institute of Theoretical Physics of CAS.
Researchers at the Institute of Modern Physics and collaborators have discovered two new isotopes, osmium-160 and tungsten-156, revealing potential for lead-164 to be a stable, doubly magic nucleus. This breakthrough enhances the understanding of nuclear stability and challenges traditional views on magic numbers, indicating a significant step forward in nuclear physics.
Scientists at the Institute of Modern Physics (IMP) under the Chinese Academy of Sciences (CAS), along with their collaborators, have created two novel isotopes—osmium-160 and tungsten-156. This discovery provides new insights into the architecture of atomic nuclei and suggests that lead-164 might possess enhanced stability as a potentially doubly magic nucleus.
The study was published in Physical Review Letters and highlighted as an Editors’ Suggestion.
“Magic numbers” of protons and neutrons can make an atomic nucleus particularly stable. The traditional magic numbers are 8, 20, 28, 50, 82 and 126. In previous studies, researchers discovered the vanishing of traditional magic numbers and the emergence of new magic numbers on the neutron-rich side of the nuclide chart.
Will other traditional magic numbers disappear in extremely neutron-deficient nuclear regions? Further exploration is of great significance to enrich and develop nuclear theories and to deepen our understanding of nuclear forces.
Experimental Achievements and Findings
In this study, researchers carried out the experiment at the gas-filled recoil separator-Spectrometer for Heavy Atoms and Nuclear Structure (SHANS), which is located at the Heavy Ion Research Facility in Lanzhou, China.
Using the fusion evaporation reaction, researchers synthesized osmium-160 and tungsten-156 for the first time. They measured the α-particle energy and the half-life of osmium-160, which is an α-emitting isotope. Meanwhile, they determined that the daughter nucleus, tungsten-156, is a β+ emitter with a half-life of 291 ms.
With the newly measured α-decay data, researchers derived the α-decay reduced width for osmium-160 and compared it with other nuclei with 84 neutrons but fewer protons. They found a surprising trend: The higher the proton number, the lower the decay rate.
Implications for Nuclear Theory and Stability
“This trend is interpreted as evidence for the strengthening of 82-neutron shell closure towards the proton drip line, which is supported by the increase of the neutron-shell gaps predicted in theoretical models,” said Dr. Yang Huabin from IMP, the first author of the paper.
Moreover, researchers suggested that the enhanced stability of 82-neutron shell closure can be attributed to the increasing closeness to the doubly magic nucleus lead-164, which might be a stable nucleus with 82 protons and 82 neutrons. Although lead-164 is predicted beyond the proton-drip line, the enhanced shell effect has the potential to make it a bound or quasi-bound nucleus.
Reference: “Discovery of New Isotopes 160Os and 156W: Revealing Enhanced Stability of the N=82 Shell Closure on the Neutron-Deficient Side” by 15 February 2024, Physical Review Letters.
DOI: 10.1103/PhysRevLett.132.072502
The study was conducted in collaboration with the University of Chinese Academy of Sciences, the Advanced Energy Science and Technology Guangdong Laboratory, Shandong University, Sun Yat-sen University, Guangxi Normal University, Tongji University, and the Institute of Theoretical Physics of CAS.