B-spline finite elements and their efficiency in solving relativistic mean field equations

Published: 1 January 1998| Version 1 | DOI: 10.17632/5w5cgvzbb9.1
W. Pöschl


Abstract A finite element method using B-splines is presented and compared with a conventional finite element method of Lagrangian type. The efficiency of both methods has been investigated at the example of a coupled nonlinear system of Dirac eigenvalue equations and inhomogeneous Klein-Gordon equations which describe a nuclear system in the framework of relativistic mean field theory. Although FEM has been applied with great success in nuclear RMF recently, a well known problem is the appearance of ... Title of program: bspFEM.cc Catalogue Id: ADHP_v1_0 Nature of problem The ground-state of a spherical nucleus is described in the framework of relativistic mean field theory in coordinate space. The model describes a nucleus as a relativistic system of baryons and mesons. Nucleons interact in a relativistic covariant manner through the exchange of virtual mesons: the isoscalar scalar sigma-meson, the isoscalar vector omega-meson and the isovector vector rho-meson. The model is based on the one boson exchange description of the nucleon-nucleon interaction. Versions of this program held in the CPC repository in Mendeley Data ADHP_v1_0; bspFEM.cc; 10.1016/S0010-4655(98)00003-4 This program has been imported from the CPC Program Library held at Queen's University Belfast (1969-2018)



Nuclear Physics, Computational Physics