A groundbreaking development in nuclear physics has emerged from the Institute of Modern Physics (IMP) of the Chinese Academy of Sciences, where researchers succeeded in synthesizing a previously elusive isotope: plutonium-227. This discovery, published in the esteemed journal Physical Review C, represents not only a significant achievement in the synthesis of transuranium isotopes but also a stepping stone for deeper exploration into the stability of nuclear shell closures.

At the heart of nuclear structure are “magic numbers,” which refer to specific counts of protons and neutrons that lead to enhanced stability within atomic nuclei. These numbers include key values such as 2, 8, 20, and larger figures like 126, which correlate with closed-shell configurations offering higher stability. Recent analyses have shown a diminishing robustness of the neutron shell closure at 126 when approaching uranium isotopes, prompting scientists to question whether this trend would continue into the heavier transuranic elements like plutonium.

To investigate this phenomenon, the researchers utilized the Heavy Ion Research Facility in Lanzhou, China, and employed a gas-filled recoil separator known as the Spectrometer for Heavy Atoms and Nuclear Structure. This experimental setup allowed the researchers to conduct fusion-evaporation reactions, thereby successfully synthesizing plutonium-227—a neutron-deficient isotope that represents the 39th new isotope reported by IMP and the first plutonium isotope achieved through Chinese scientific efforts.

The synthesis of plutonium-227 marks a significant milestone not only in scientific discovery but also contributes valuable data to the field of nuclear physics. By examining nine observed decay chains, the researchers were able to determine the decay characteristics of this isotope, measuring its alpha-particle energy to be approximately 8191 keV, with a half-life of about 0.78 seconds. These results align well with existing systematic studies of plutonium isotopes.

The implications of this discovery extend beyond the isotope itself, as researchers seek to deepen their understanding of the evolution of nuclear shell closures in plutonium. With plutonium-227 still seven neutrons shy of the theoretical magic number of 126, further studies aiming to synthesize lighter plutonium isotopes, specifically plutonium-221 to plutonium-226, are planned. According to Dr. Yang Huabin of IMP, understanding the behavior of these isotopes is crucial for validating the neutron shell closures and exploring nuclear configurations in this region.

The successful synthesis of plutonium-227 is a compelling advancement in nuclear physics, offering crucial insights into the complexities of atomic structure. It provides a unique opportunity to explore the robustness of nuclear shell closures and furthers our understanding of nuclear stability in transuranic elements. As research continues, the findings will contribute to both theoretical models and practical applications within nuclear science, solidifying the role of international collaborations in unearthing the mysteries of matter at its most fundamental levels.

Science

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