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XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept. 21-25, Ka

XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept. 21-25, Kazimierz Dolny, Poland. Self-Consistent Description of Collective Excitations in the Unitary Correlation Operator Model .

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XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept. 21-25, Ka

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  1. XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept. 21-25, Kazimierz Dolny, Poland Self-Consistent Description of Collective Excitations in the Unitary Correlation Operator Model N. Paar, P. Papakonstantinou, R. Roth, and H. Hergert

  2. Realistic and Effective Nucleon-Nucleon Interactions Realistic nucleon-nucleon interactions are determined from the phase-shift analysis of nucleon-nucleon scattering strong repulsive core at small distances ~ 0.5 fm Very large or infinite matrix elements of interaction (relative wave functions penetrate the core) AV18, central part (S,T)=(0,1) 4He C Effective nucleon-nucleon interaction Realistic nucleon- nucleon interaction

  3. THE UNITARY CORRELATION OPERATOR METHOD Short-range central and tensor correlations are included in the simple many body states via unitary transformation CORRELATED MANY-BODY STATE UNCORRELATED MANY-BODY STATE UNCORRELATED OPERATOR CORRELATED OPERATOR Instead of correlated many-body states, the correlated operators are employed in nuclear structure models of finite nuclei R. Roth et al., Nucl. Phys. A 745, 3 (2004) H. Feldmeier et al., Nucl. Phys. A 632, 61 (1998) T. Neff et al., Nucl. Phys. A 713, 311 (2003) R. Roth et al., Phys. Rev. C 72, 034002 (2005)

  4. DEUTERON: MANIFESTATION OF CORRELATIONS Spin-projected two-body density of the deuteron for AV18 potential TWO-BODY DENSITY FULLY SUPPRESSED AT SMALL PARTICLE DISTANCES ANGULAR DISTRIBUTION DEPENDS STRONGLY ON RELATIVE SPIN ORIENTATION CENTRAL CORRELATIONS TENSOR CORRELATIONS

  5. THE UNITARY CORRELATION OPERATOR METHOD 40 Argonne V18 Potential Correlation functions are constrained by the energy minimization in the two-body system 12 Central Correlator Cr TWO-NUCLEON SYSTEM 6 Additional constraints necessary to restrict the ranges of the correlation functions Tensor Correlator CΩ Two-Body Approximation 2 VUCOM Hartree-Fock FINITE NUCLEI ? Fermionic Molecular Dynamics 3-Nucleon Interaction Random Phase Approximation No-core Shell Model

  6. CORRELATED REALISTIC NN INTERACTION - VUCOM Closed operator expression for the correlated interaction VUCOM in two-body approximation Correlated interaction and original NN-potential are phase shift equivalent by construction Central and tensor correlations are essential to obtain bound nuclear system Momentum-space matrix elements of the correlated interaction VUCOM are similar to low-momentum interaction Vlow-k

  7. WHAT IS OPTIMAL RANGE FOR THE TENSOR CORRELATOR? NO-CORE SHELL MODEL CALCULATIONS USING VUCOM POTENTIAL R. Roth et al, nucl-th/0505080 Increasing range of the tensor correlator SELECT A CORRELATOR WITH ENERGY CLOSE TO EXPERIMENTAL VALUE CANCELLATION OF OMMITED 3-BODY CONTRIBUTIONS OF THE CLUSTER EXPANSION AND GENUINE 3-BODY FORCE VNN+V3N

  8. Hartree-Fock Model Based on Correlated Realistic NN-potential Nucleons are moving in an average single-particle potential Expansion of the single-particle state in harmonic-oscillator basis Matrix formulation of Hartree-Fock equations as a generalized eigenvalue problem Restrictions on the maximal value of the major shell quantum number NMAX=12 and orbital angular momentum lMAX=8

  9. UCOM Hartree-Fock Single-Particle Spectra

  10. UCOM Hartree-Fock Binding Energies & Charge Radii Long-range correlations ? 3-body interaction

  11. UCOM Random-Phase Approximation Low-amplitude collective oscillations Vibration creation operator (1p-1h): Equations of motion  RPA & Fully-self consistent RPA model: there is no mixing between the spurious 1- state and excitation spectra VUCOM EXCITATION ENERGIES Sum rules: Є=±3%

  12. UCOM-RPA Isoscalar Giant Monopole Resonance Various ranges of the UCOM tensor correlation functions Relativistic RPA (DD-ME1 interaction)

  13. UCOM-RPA Isovector Giant Dipole Resonance Various ranges of the UCOM tensor correlation functions

  14. UCOM-RPA Giant Quadrupole Resonance THE CORRELATED REALISTIC NN INTERACTION GENERATES THE LOW-LYING 2+ STATE AND GIANT QUADRUPOLE RESONANCE

  15. UCOM-RPA Isoscalar Giant Quadrupole Resonance Various ranges of the UCOM tensor correlation functions

  16. UCOM-RPA GROUND-STATE CORRELATIONS Variation of the range of the tensor correlation function in (S=1,T=0) channel Part of the missing long-range correlations in UCOM-Hartree-Fock model is reproduced by the RPA correlations NMAX=12 & lMAX=8

  17. SUMMARY The unitary correlation operator model (UCOM) provides an effective interaction suitable for the nuclear structure models UCOM Hartree-Fock model results with underbinding and small radii  necessity for long-range correlations (recovered by RPA & perturbation theory) and the three-body interaction Fully self-consistent UCOM Random-Phase Approximation (RPA) is constructed in the UCOM Hartree-Fock single-nucleon basis Correlated realistic NN interaction generates collective excitation modes, however it overestimates IVGDR and ISGQR energies Optimization of the constraints for the ranges of correlators Damping, couplings of complex configurations, Second RPA Three-body interaction

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