Breakthrough Sharpens Atomic Nuclei Measurements

Nuclear Science and Techniques

Researchers at the Heavy Ion Research Facility in Lanzhou (HIRFL-CSR) have introduced a technique, Tune-IMS, designed to improve the precision of isochronous mass spectrometry (IMS) in measuring short-lived atomic nuclei. The development offers refined data for nuclear structure studies and could have potential applications in astrophysics, nuclear energy, and medicine.

Enhancing Precision in Nuclear Mass Measurements

The Tune-IMS technique has proven its capability to enhance the mass precision of certain short-lived nuclei, such as 63Ge, 65As, 67Se, and 71Kr. Compared with previous IMS method, it additionally utilizes betatron oscillation of the ions to further reduce the mass errors, which is particularly important for short-lived nuclides."Our method can achieve higher precision for isotopes that have been challenging to measure," said Prof. Meng Wang, lead researcher on the project. "This may benefit ongoing studies in nuclear physics and related fields."

Applications in Nuclear Research and Beyond

The improved precision provided by Tune-IMS may offer more reliable data for researchers studying nuclear reactions, which are important for understanding processes such as stellar evolution and the formation of elements in stars. More accurate mass measurements could also contribute to nuclear energy research, where precise data can enhance the efficiency of reactors and improve safety protocols.

In addition, the advancement may assist in nuclear medicine, where isotopes used in diagnostic imaging and therapeutic treatments require accurate mass data for stability and effectiveness.

Addressing Previous Limitations in IMS

Conventional isochronous mass spectrometry (IMS) has faced challenges in achieving high accuracy, particularly with short-lived nuclei. These limitations have been tied to the spread of magnetic rigidity in ions, which can affect the resolution of mass measurements.

The Tune-IMS technique addresses this issue by utilizing betatron oscillations, which reduce the spread in revolution times and thus improve measurement precision. This method has been successfully tested on several nuclides and has compared favorably with established IMS methods.

Future Research Directions

While Tune-IMS offers improvements, the current method requires the selection of specific oscillation values, which limits the number of ions available for analysis. The research team is developing a new time-of-flight detector with positional sensitivity to address this limitation, aiming to increase the method's efficiency and applicability.

"By improving the sensitivity of our detectors, we hope to expand the range of nuclei that can be studied with Tune-IMS," Prof. Wang noted.

Conclusion

The Tune-IMS technique represents a refinement in the precision of mass measurements for short-lived atomic nuclei, with potential applications in both fundamental nuclear research and practical fields like nuclear energy and medicine. Researchers at HIRFL-CSR plan to continue developing the technology to broaden its scope. The complete study is accessible via https://link.springer.com/article/10.1007/s41365-024-01580-5.

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