“Quantum” molecular dynamics—a dynamical microscopic n-body approach to investigate fragment formation and the nuclear equation of state in heavy ion collisions

A guide to microscopic models for intermediate energy heavy ion collisions

A Skyrme parametrization from subnuclear to neutron star densities

Shape coexistence in nuclei appears to be unique in the realm of finite many-body quantum systems It differs from the various geometrical arrangements that sometimes occur in a molecule in that in a molecule the various arrangements are of the widely separated atomic nuclei In nuclei the various ''arrangements'' of nucleons involve (sets of) energy eigenstates with different electric quadrupole properties such as moments and transition rates, and different distributions of proton pairs and neutron pairs with respect to their Fermi energies Sometimes two such structures will ''invert'' as a function of the nucleon number, resulting in a sudden and dramatic change in ground-state properties in neighboring isotopes and isotones In the first part of this review the theoretical status of coexistence in nuclei is summarized Two approaches, namely, microscopic shell-model descriptions and mean-field descriptions, are emphasized The second part of this review presents systematic data, for both even- and odd-mass nuclei, selected to illustrate the various ways in which coexistence is observed in nuclei The last part of this review looks to future developments and the issue of the universality of coexistence in nuclei Surprises continue to be discovered With the major advances in reaching to extremes of proton-neutronmore » number, and the anticipated new ''rare isotope beam'' facilities, guidelines for search and discovery are discussed« less

Shape coexistence in atomic nuclei

Reaction dynamics with exotic nuclei

Semi-classical dynamics of heavy-ion reactions

Fluctuations in one-body dynamics

Semiclassical and phase space approaches to dynamic and collisional problems of nuclei

A theoretical analysis of collective momentum transfer is performed in heavy-ion reactions below 100 MeV/nucleon in the Landau-Vlasov approach. The nucleon-nucleon cross section, atomic mass, compressibility, and effective mass dependences are analyzed. The simulation of detector acceptances and of finite number of detected particles are discussed. In connection with recent experiments, theoretical results and experimental data are confronted taking into account the experimental constraints. Finite range forces of the Gogny type connected with different nuclear matter incompressibilities are used and the ensuing sensitivity of the flow is studied. The question whether the flow provides information on out-of-equilibrium matter properties is investigated.

Analysis of the transverse momentum collective motion in heavy-ion collisions below 100 MeV/nucleon.

Fast fission phenomenon, deep inelastic reactions and compound nucleus formation described within a dynamical macroscopic model

B. Remaud

Papers

Semi-classical dynamics of heavy-ion reactions

Fluctuations in one-body dynamics

Semiclassical and phase space approaches to dynamic and collisional problems of nuclei

Analysis of the transverse momentum collective motion in heavy-ion collisions below 100 MeV/nucleon.

Fast fission phenomenon, deep inelastic reactions and compound nucleus formation described within a dynamical macroscopic model