A five-dimensional model has successfully predicted the asymmetric fission of mercury isotopes, offering new insights into nuclear fission processes beyond the well-studied elements uranium and plutonium. A five-dimensional (5D) Langevin model developed by an international team of researchers, including scientists from Science Tokyo, has accurately reproduced complex fission fragment distributions and kinetic energies in medium-mass […]



Summary

A 5D Langevin model accurately predicts the asymmetric fission of mercury isotopes, offering a breakthrough in understanding fission beyond uranium and plutonium. This model, developed by an international team including scientists from Science Tokyo, successfully reproduces the complex fission fragment distributions and kinetic energies observed in medium-mass nuclei. The research challenges previous assumptions about fission symmetry, demonstrating the model’s ability to capture intricate dynamics and providing a valuable tool for studying nuclear fission across a wider range of elements. This work expands our knowledge of the fundamental processes governing nuclear fission.

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