Nuclear and Particle Physics, Astrophysics and Cosmology, T-2

Inelastic Scattering Microscopic Calculations with Second Order Born Approximation, link with FKK Pre-Equilibrium Formalism

Eric Bauge
CEA-DIF, BRC, France

In a collision between a nucleon and a target nucleus at medium incident energy, several reactions occur, among them elastic and inelastic scatterings, particles emissions, nucleon transfer, knock-out \x{2026}. In order to describe or predict the observables associated with these reactions, different kind of reaction processes are involved, such as direct, pre-equilibrium reactions, and compound nucleus formation and decay. Our goal is to describe elastic and inelastic scattering off double-magic nuclei coming from direct and preequilibrium processes by avoiding phenomenological ingredients. For direct processes, we will review our previous results obtained from fully microscopic optical model potential (OMP) calculations. This OMP is constructed from the Melbourne-g matrix taken as the two-body interaction between the projectile and target nucleons and a RPA (Random Phase Approximation) description of the target nucleus, including correlated ground state. Inelastic scattering is then calculated using RPA description of the target excited states, within the DWBA framework. The results are in fair agreement with experimental data. This allows us to go further and use these ingredients to describe processes beyond the scope of direct reactions. Among such processes, inelastic scattering with high energy transfer cannot been described using only DWBA calculations. We will focus on inelastic scattering calculations using the Born expansion of the transition amplitude up to the second order and its link with theoretical approaches of pre-equilibrium reactions such as the FKK (Feshbach, Kerman, Koonin) model. Indeed the FKK approach involves several kind of approximations of the Born expansion of the transition amplitude which have not yet been tested. Comparisons between second order calculations and FKK model predictions allow us to test these approximations, and allows us to discuss on the validity of the FKK model and give some directions to improve the theory.

Contact Us | Careers | Bradbury Science Museum | Emergencies | Inside LANL | Maps | Site Feedback | SSL Portal | Training

Operated by Los Alamos National Security, LLC for the U.S. Department of Energy's NNSA © Copyright 2014 LANS, LLC All rights reserved | Terms of Use | Privacy Policy