Abstract
We have decomposed to symmetric and asymmetric modes the mass-TKE fission fragment distributions calculated by 4-dimensional Langevin approach and observed how the dominant fission mode and symmetric mode change as functions of {Z}^{2}/sqrt[3]{A} of the fissioning system in the actinides and trans-actinide region. As a result, we found that the symmetric mode makes a sudden transition from super-long to super short fission mode around 254Es. The dominant fission modes on the other hand, are persistently asymmetric except for 258Fm, 259Fm and 260Md when the dominant fission mode suddenly becomes symmetric although it returns to the asymmetric mode around 256No. These correlated “twin transitions” have been known empirically by Darleane Hoffman and her group back in 1989, but for the first time we have given a clear explanation in terms of a dynamical model of nuclear fission. More specifically, since we kept the shape model parameters unchanged over the entire mass region, we conclude that the correlated twin transition emerge naturally from the dynamics in 4-D potential energy surface.
Highlights
4-D Langevin calculated fission yield ( ) and the approximation to 3-D Langevin ( ) for 256Fm on the left and 258Fm on the right
Comparison with experimental data ( ) for 256Fm22 and 258Fm14 are made for the respective figure from left to right
Our analysis of δ distribution indicates that the allowance for δ in our 4-D Langevin calculation showed us multiple fission paths dependent on the combinations of δL and δH
Summary
4-D Langevin calculated fission yield ( ) and the approximation to 3-D Langevin ( ) for 256Fm on the left and 258Fm on the right.
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