D. Vretenar, G. A. Lalazissis, R. Behnsch, W. Pöschl, P. Ring
Published 1996-12-16Version 1
Isoscalar and isovector monopole oscillations that correspond to giant resonances in spherical nuclei are described in the framework of time-dependent relativistic mean-field (RMF) theory. Excitation energies and the structure of eigenmodes are determined from a Fourier analysis of dynamical monopole moments and densities. The generator coordinate method, with generating functions that are solutions of constrained RMF calculations, is also used to calculate excitation energies and transition densities of giant monopole states. Calculations are performed with effective interactions which differ in their prediction of the nuclear matter compression modulus K_nm. Both time-dependent and constrained RMF results indicate that empirical GMR energies are best reproduced by an effective force with K_nm \approx 270 MeV.
Comments: 30 pages of LaTeX, 18 PS-figures
Systematic Study of Triaxial Deformation in the Relativistic Mean Field Theory
Isospin Dependence of Proton and Neutron Radii within Relativistic Mean Field Theory
In-medium Properties of $Θ^{+}$ as a K$π$N structure in Relativistic Mean Field Theory
