T. Frick, H. Müther, A. Rios, A. Polls, A. Ramos
Published 2004-09-28Version 1
The single-particle spectral functions in asymmetric nuclear matter are computed using the ladder approximation within the theory of finite temperature Green's functions. The internal energy and the momentum distributions of protons and neutrons are studied as a function of the density and the asymmetry of the system. The proton states are more strongly depleted when the asymmetry increases while the occupation of the neutron states is enhanced as compared to the symmetric case. The self-consistent Green's function approach leads to slightly smaller energies as compared to the Brueckner Hartree Fock approach. This effect increases with density and thereby modifies the saturation density and leads to smaller symmetry energies.
Comments: 7 pages, 7 figures
Journal: Phys.Rev. C71 (2005) 014313
Sum rules of single-particle spectral functions in hot asymmetric nuclear matter
Cavitation and bubble collapse in hot asymmetric nuclear matter
Isospin dependence of liquid-gas phase transition in hot asymmetric nuclear matter
