Shan-Gui Zhou URL: 1.Institute of Theoretical Physics,

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Presentation transcript:

Shan-Gui Zhou URL: 1.Institute of Theoretical Physics, Chinese Academy of Sciences, Beijing 2.Center of Theoretical Nuclear Physics, National Laboratory of Heavy Ion Accelerator, Lanzhou Structure of exotic nuclei from relativistic Hartree Bogoliubov model (I) HISS-NTAA 2007 Dubna, Aug. 7-17

Introduction to ITP and CAS  Chinese Academy of Sciences (CAS)  Independent of Ministry of Education, but award degrees (Master and Ph.D.)  ~120 institutes in China; ~50 in Beijing  Almost all fields  Institute of Theoretical Physics (ITP)  smallest institute in CAS  ~40 permanent staffs; ~20 postdocs; ~120 students  Atomic, nuclear, particle, cosmology, condensed matter, biophysics, statistics, quantum information  Theor. Nucl. Phys. Group  Super heavy nuclei  Structure of exotic nuclei

Contents  Introduction to Relativistic mean field model  Basics: formalism and advantages  Pseudospin and spin symmetries in atomic nuclei  Pairing correlations in exotic nuclei  Contribution of the continuum  BCS and Bogoliubov transformation  Spherical relativistic Hartree Bogoliubov theory  Formalism and results  Summary I  Deformed relativistic Hartree Bogoliubov theory in a Woods-Saxon basis  Why Woods-Saxon basis  Formalism, results and discussions  Single particle resonances  Analytical continuation in coupling constant approach  Real stabilization method  Summary II

Relativistic mean field model Lagrangian density Non-linear coupling for  Field tensors Reinhard, Rep. Prog. Phys. 52 (89) 439 Ring, Prog. Part. Nucl. Phys. 37 (96) 193 Vretenar, Afnasjev, Lalazissis & Ring Phys. Rep. 409 (05) 101 Meng, Toki, SGZ, Zhang, Long & Geng, Prog. Part. Nucl. Phys. 57 (06) 470 Serot & Walecka, Adv. Nucl. Phys. 16 (86) 1

Coupled equations of motion Nucleon Mesons & photon Vector & scalar potentials Sources (densities) Solving Eqs.: no-sea and mean field approximations; iteration

RMF for spherical nuclei Dirac spinor for nucleon Radial Dirac Eq. Vector & scalar potentials

RMF for spherical nuclei Klein-Gordon Eqs. for mesons and photon Sources Densities

RMF potentials

RMF for spherical nuclei: observables Nucleon numbers Radii Total binding energy

Center of mass corrections Long, Meng, Giai, SGZ, PRC69,034319(04)

 Nucleon-nucleon interaction  Mesons degrees of freedom included  Nucleons interact via exchanges mesons  Relativistic effects  Two potentials: scalar and vector potentials  the relativistic effects important dynamically  New mechanism of saturation of nuclear matter  Psedo spin symmetry explained neatly and successfully  Spin orbit coupling included automatically  Anomalies in isotope shifts of Pb  Others  More easily dealt with  Less number of parameters  … RMF description of exotic nuclei: Why?

Potentials in the RMF model

Properties of Nuclear Matter Brockmann & Machleidt PRC42, 1965 (1990) E/A =  16  1 MeV k F = 1.35  0.05 fm  1 Coester band

Isotope shifts in Pb Sharma, Lalazissis & Ring PLB317, 9 (1993) RMF

 Ground state properties of nuclei  Binding energies, radii, neutron skin thickness, etc.  Symmetries in nuclei  Pseudo spin symmetry  Spin symmetry  Halo nuclei  RMF description of halo nuclei  Predictions of giant halo  Study of deformed halo  Hyper nuclei  Neutron halo and hyperon halo in hyper nuclei  … RMF (RHB) description of nuclei Vretenar, Afnasjev, Lalazissis & Ring Phys. Rep. 409 (05) 101 Meng, Toki, Zhou, Zhang, Long & Geng, Prog. Part. Nucl. Phys. 57 (06) 470

Contents  Introduction to Relativistic mean field model  Basics: formalism and advantages  Pseudospin and spin symmetries in atomic nuclei  Pairing correlations in exotic nuclei  Contribution of the continuum  BCS and Bogoliubov transformation  Spherical relativistic Hartree Bogoliubov theory  Formalism and results  Summary I  Deformed relativistic Hartree Bogoliubov theory in a Woods-Saxon basis  Why Woods-Saxon basis  Formalism, results and discussions  Single particle resonances  Analytical continuation in coupling constant approach  Real stabilization method  Summary II

Spin and pseudospin in atomic nuclei Hecht & Adler NPA137(1969)129 Arima, Harvey & Shimizu PLB30(1969)517 Woods-Saxon

Spin and pseudospin in atomic nuclei  Spin symmetry is broken  Large spin-orbit splitting  magic numbers  Approximate pseudo-spin symmetry  Similarly to spin, no partner for  ? Origin  ? Different from spin, no partner for, e.g.,  ? (n+1, n) & nodal structure  PS sym. more conserved in deformed nuclei  Superdeformation, identical bands etc. Ginocchio, PRL78(97)436 Ginocchio & Leviatan, PLB518(01)214 Chen, Lv, Meng & SGZ, CPL20(03)358 Ginocchio, Leviatan, Meng & SGZ, PRC69(04)034303

Pseudo quantum numbers Pseudo quantum numbers are nothing but the quantum numbers of the lower component. Ginocchio PRL78(97)436

Origin of the symmetry - Nucleons For nucleons,  V(r)  S(r)=0  spin symmetry V(r)  S(r)=0  pseudo-spin symmetry Schroedinger-like Eqs.

Origin of the symmetry - Anti-nucleons For anti-nucleons,  V(r)+S(r)=0  pseudo-spin symmetry V(r)  S(r)=0  spin symmetry SGZ, Meng & Ring PRL92(03) Schroedinger-like Eqs.

Spin symmetry in anti-nucleon more conserved For nucleons, the smaller component F For anti-nucleons, the larger component F SGZ, Meng & Ring PRL92(03) The factor is ~100 times smaller for anti nucleons!

O: anti neutron levels p 1/2 p 3/2 M  [V(r)  S(r)] [MeV] SGZ, Meng & Ring, PRL91, (2003) p 1/2 p 3/2

Spin orbit splitting SGZ, Meng & Ring, PRL91, (2003)

Wave functions for PS doublets in 208 Pb Ginocchio&Madland, PRC57(98)1167

Wave functions SGZ, Meng & Ring, PRL92(03)262501

Wave functions SGZ, Meng & Ring, PRL92(03)262501

Wave functions SGZ, Meng & Ring, PRL92(03)262501

Wave functions: relation betw. small components He, SGZ, Meng, Zhao, Scheid EPJA28( 2006) 265

Wave functions: relation betw. small components He, SGZ, Meng, Zhao, Scheid EPJA28( 2006) 265

Contents  Introduction to Relativistic mean field model  Basics: formalism and advantages  Pseudospin and spin symmetries in atomic nuclei  Pairing correlations in exotic nuclei  Contribution of the continuum  BCS and Bogoliubov transformation  Spherical relativistic Hartree Bogoliubov theory  Formalism and results  Summary I  Deformed relativistic Hartree Bogoliubov theory in a Woods-Saxon basis  Why Woods-Saxon basis  Formalism, results and discussions  Single particle resonances  Analytical continuation in coupling constant approach  Real stabilization method  Summary II

Characteristics of halo nuclei  Weakly bound; large spatial extension  Continuum can not be ignored

BCS and Continuum Bound States Positive energy States Even a smaller occupation of positive energy states gives a non-localized density Dobaczewski, et al., PRC53(96)2809

Contribution of continuum in r-HFB When r goes to infinity, the potentials are zero U and V behave when r goes to infinity Bulgac, 1980 & nucl-th/ Dobaczewski, Flocard&Treiner, NPA422(84)103 Continuum contributes automatically and the density is still localized

Contribution of continuum in r-HFB Dobaczewski, et al., PRC53(96)2809 V(r) determines the density the density is localized even if U(r) oscillates at large r Positive energy States Bound States

Spherical relativistic continuum Hartree Bogoliubov (RCHB) theory RHB Hamiltonian Pairing tensor Baryon density Pairing force

Spherical relativistic continuum Hartree Bogoliubov (RCHB) theory Pairing force Radial DHB Eqs.

Spherical relativistic continuum Hartree Bogoliubov (RCHB) theory Densities Total binding energy

Li ： self-consistent RCHB description Meng & Ring, PRL77,3963 (96) RCHB reproduces expt.

Li ： self-consistent RCHB description Meng & Ring, PRL77,3963 (96) Contribution of continuum Important roles of low-l orbitals close to the threshold

Giant halo: predictions of RCHB Meng & Ring, PRL80,460 (1998) Halos consisting of up to 6 neutrons Important roles of low-l orbitals close to the threshold

Prediction of giant halo Meng, Toki, Zeng, Zhang & SGZ, PRC65,041302R (2002) Zhang, Meng, SGZ & Zeng, CPL19,312 (2002) Zhang, Meng & SGZ, SCG33,289 (2003) Giant halos in lighter isotopes

Giant halo from Skyrme HFB and RCHB Terasaki, Zhang, SGZ, & Meng, PRC74 (2006) Giant halos from non-rela. HFB Different predictions for drip line

Halos in hyper nuclei Lv, Meng, Zhang & SGZ, EPJA17 (2002) 19 Meng, Lv, Zhang & SGZ, NPA722c (2003) 366 Additional binding from 

Densities and charge changing cross sections Meng, SGZ, & Tanihata, PLB532 (2002)209 Proton density as inputs of Glauber model

Summary I  Relativistic mean field model  Basics: formalism and advantages  Pseudospin and spin symmetries in atomic nuclei  Relativistic symmetries: cancellation of the scalar and vector potentials  Spin symmetry in anti nucleon spectra is more conserved  Tests of wave functions  Pairing correlations in exotic nuclei  Contribution of the continuum: r space HFB or RHB  Spherical relativistic Hartree Bogoliubov theory  Self consistent description of halo  Predictions of giant halo and halo in hyper nuclei  Charge changing cross sections