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Thesis
Home   /   Thesis   /   Microscopic nuclear structure models to study de-excitation process in nuclear fission

Microscopic nuclear structure models to study de-excitation process in nuclear fission

Corpuscular physics and outer space Nuclear physics Theoretical physics

Abstract

The FIFRELIN code is being developed at CEA/IRESNE Cadarache in order to provide a detailed description of the fission process and to calculate all relevant fission observables accurately. The code heavily resides on the detailed knowledge of the underlying structure of the nuclei involved in the post-fission de-excitation process. When possible, the code relies on nuclear structure databases such as RIPL-3 that provide valuable information on nuclear level schemes, branching ratios and other critical nuclear properties. Unfortunately, not all these quantities have been measured, nuclear models are therefore used instead.

The development of state-of-the-art nuclear models is the task of the newly-formed nuclear theory group at Cadarache, whose main expertise is the implementation of nuclear many-body solvers based on effective nucleon-nucleon interactions.

The goal of this thesis is to quantify the impact of the E1/M1 and E2/M2 strength functions on fission observables. Currently, this quantity is estimated using simple models such as the generalized Lorentzian. The doctoral student will be tasked with replacing these models by fully microscopic ones based on effective nucleon-nucleon interaction via QRPA-type techniques. A preliminary study shows that the use of macroscopic (generalized Lorentzian) or microscopic (QRPA) has a non-negligible impact on fission observables.

Professional perspectives for the student include academic research as well as theoretical and applied nuclear R&D.

Laboratory

Département Etude des Réacteurs
Service de Physique des Réacteurs et du Cycle
Laboratoire d’Etudes de PHysique
Grenoble INP
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