Abstract
Fission yields are essential for nuclear reactor studies (decay heat, fuel inventory…) and constitute also one of the main observables needed to improve our understanding of the fission process. The symmetric mass region is of particular interest due to various intriguing properties of the fission fragments already reported in the literature : inversion of the nuclear charge polarization, large width of the fission fragment kinetic energy distribution, strong change of the prompt neutron multiplicity, etc. Recently, measurements of fission yields and kinetic energy distributions in the symmetric mass region were achieved at the LOHENGRIN mass spectrometer of the Institut Laue-Langevin (ILL). This experimental work is challenging due to the low counting rate and the appearance of contaminant masses, leading to pronounced components in the fission fragment kinetic energy distribution. Despite removing the undesirable contributions, the fission fragment kinetic energy distributions still show two components, indicating that the fission process could be modal. To go further and better characterize these components a comparison between our experimental data and Monte Carlo calculations (FIFRELIN code) simulating the de-excitation of the fission fragments for different fission channels will be presented and discussed.
Highlights
As computing power grows, studies of innovative nuclear reactor concepts more and more rely on complex multiphysics modelling
FIFRELIN is a Monte Carlo code developed at CEA Cadarache [3,4,5]
We remind that FIFRELIN calculations require input data such as pre-neutron emission mass yield and the total kinetic energy mean and width per mass
Summary
Studies of innovative nuclear reactor concepts more and more rely on complex multiphysics modelling. These simulations require among others accurate knowledge of fission data in the actinide region. The construction of a covariance matrix associated to the experimental data is the keystone of these efforts. Another way for improving the evaluation of nuclear data is to develop the modelling of the fission phenomenon. The uncertainties of these data would be reduced as long as our knowledge of the fission process would get better In this way, the symmetric region is a good laboratory to test model hypotheses. New measurements on the LOHENGRIN mass spectrometer [1] of the Institut Laue-Langevin (ILL)
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