541 research outputs found

    Neutron rich nuclei in density dependent relativistic Hartree-Fock theory with isovector mesons

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    Density dependent relativistic Hartree-Fock theory has been extended to describe properties of exotic nuclei. The effects of Fock exchange terms and of pi - and rho - meson contributions are discussed. These effects are found to be more important for neutron rich nuclei than for nuclei near the valley of stability.Comment: 10 pages, 5 figures, LaTeX, macro packages graphicx and time

    Relativistic Equation of State of Nuclear Matter for Supernova and Neutron Star

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    We construct the equation of state (EOS) of nuclear matter using the relativistic mean field (RMF) theory in the wide density, temperature range with various proton fractions for the use of supernova simulation and the neutron star calculations. We first construct the EOS of homogeneous nuclear matter. We use then the Thomas-Fermi approximation to describe inhomogeneous matter, where heavy nuclei are formed together with free nucleon gas. We discuss the results on free energy, pressure and entropy in the wide range of astrophysical interest. As an example, we apply the resulting EOS on the neutron star properties by using the Oppenheimer-Volkoff equation.Comment: 15 pages, LaTeX, 14 ps-figures, accepted for publication in Nucl.Phys.

    Effective DBHF Method for Asymmetric Nuclear Matter and Finite Nuclei

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    A new decomposition of the Dirac structure of nucleon self-energies in the Dirac Brueckner-Hartree-Fock (DBHF) approach is adopted to investigate the equation of state for asymmetric nuclear matter. The effective coupling constants of σ\sigma , ω\omega , δ\delta and ρ\rho mesons with a density dependence in the relativistic mean field approach are deduced by reproducing the nucleon self-energy resulting from the DBHF at each density for symmetric and asymmetric nuclear matter. With these couplings the properties of finite nuclei are investigated. The agreement of charge radii and binding energies of finite nuclei with the experimental data are improved simultaneously in comparison with the projection method. It seems that the properties of finite nuclei are sensitive to the scheme used for the DBHF self-energy extraction. We may conclude that the properties of the asymmetric nuclear matter and finite nuclei could be well described by the new decomposition approach of the G matrix.Comment: 16 pages, 5 figure

    Density-Dependent Relativistic Hartree-Fock Approach

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    A new relativistic Hartree-Fock approach with density-dependent σ\sigma, ω\omega, ρ\rho and π\pi meson-nucleon couplings for finite nuclei and nuclear matter is presented. Good description for finite nuclei and nuclear matter is achieved with a number of adjustable parameters comparable to that of the relativistic mean field approach. With the Fock terms, the contribution of the π\pi-meson is included and the description for the nucleon effective mass and its isospin and energy dependence is improved.Comment: 4 pages, 3 figure

    Bulk properties of light deformed nuclei derived from a medium-modified meson-exchange interaction

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    Deformed Hartree-Fock-Bogoliubov calculations for finite nuclei are carried out. As residual interaction, a Brueckner G-matrix derived from a meson-exchange potential is taken. Phenomenological medium modifications of the meson masses are introduced. The binding energies, radii, and deformation parameters of the Carbon, Oxygen, Neon, and Magnesium isotope chains are found to be in good agreement with the experimental data.Comment: 10 pages, LaTeX2e, elsart, 4 eps-figures includes with graphic

    Strange Particles in Dense Matter and Kaon Condensates

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    We discuss the role of strangeness in dense matter and especially in neutron stars. The early (in density) introduction of hyperons found in many calculations is probably delayed by the decrease in vector mean field acting on the neutron. The decrease results from both conventional many-body rescattering effects and from the movement towards asymptotic freedom at high densities. Subthreshold KK^--meson production by the KaoS collaboration at GSI shows that the KK^--mass must be substantially lowered, by \gtrsim 200 MeV at ρ2ρ0\rho\sim 2\rho_0. It is shown that explicit chiral symmetry breaking through the kaon mass may be responsible for Σ\Sigma^--nucleon and Ξ\Xi^--nucleon scalar attraction being weaker than obtained by simple quark scaling. The normal mode of the strangeness minus, charge ee^-, excitation is constructed as a linear combination of KK^--meson and Σ\Sigma^-, neutron-hole state. Except for zero momentum, where the terms are unmixed the "kaesobar" is a linear combination of these two components.Comment: 10 pages, 8 postscript figures, Talk given at the International Conference on Hypernuclear and Strange Particle Physics (HYP97), Brookhaven Nat'l Lab., USA, October 13-18, 1997, to be published in Nucl. Phys.

    What do we learn from correlations of local and global network properties?

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    In complex networks a common task is to identify the most important or "central" nodes. There are several definitions, often called centrality measures, which often lead to different results. Here we study extensively correlations between four local and global measures namely the degree, the shortest-path-betweenness, the random-walk betweenness and the subgraph centrality on different random-network models like Erdos-Renyi, Small-World and Barabasi-Albert as well as on different real networks like metabolic pathways, social collaborations and computer networks. Correlations are quite different between the real networks and the model networks questioning whether the models really reflect all important properties of the real world

    Nuclear and Neutron Matter Calculations with Different Model Spaces

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    In this work we investigate the so-called model-space Brueckner-Hartree-Fock (MBHF) approach for nuclear matter as well as for neutron matter and the extension of this which includes the particle-particle and hole-hole (PPHH) diagrams. A central ingredient in the model-space approach for nuclear matter is the boundary momentum kMk_M beyond which the single-particle potential energy is set equal to zero. This is also the boundary of the model space within which the PPHH diagrams are calculated. It has been rather uncertain which value should be used for kMk_M. We have carried out model-space nuclear matter and neutron matter calculations with and without PPHH diagrams for various choices of kMk_M and using several modern nucleon-nucleon potentials. Our results exhibit a saturation region where the nuclear and neutron matter matter energies are quite stable as kMk_M varies. The location of this region may serve to determine an "optimum" choice for kMk_M. However, we find that the strength of the tensor force has a significant influence on binding energy variation with kMk_M. The implications for nuclear and neutron matter calculations are discussed.Comment: 24 pages, Elsevier LaTeX style, 17 figs include

    Properties of charmed and bottom hadrons in nuclear matter: A plausible study

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    Changes in properties of heavy hadrons with a charm or a bottom quark are studied in nuclear matter. Effective masses (scalar potentials) for the hadrons are calculated using quark-meson coupling model. Our results also suggest that the heavy baryons containing a charm or a bottom quark will form charmed or bottom hypernuclei, which was first predicted in mid 70's. In addition a possibility of BB^--nuclear bound (atomic) states is briefly discussed.Comment: Latex, 11 pages, 3 figures, text was expanded substantially, version to appear in Phys. Lett.
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