0 Yoko Ogawa (RCNP/Osaka) Hiroshi Toki (RCNP/Osaka) Setsuo Tamenaga (RCNP/Osaka) Hong Shen (Nankai/China) Atsushi Hosaka (RCNP/Osaka) Satoru Sugimoto (RIKEN)

Slides:

Advertisements

Similar presentations

1 Eta production Resonances, meson couplings Humberto Garcilazo, IPN Mexico Dan-Olof Riska, Helsinki … exotic hadronic matter?

Advertisements

反対称化分子動力学でテンソル力を取り扱う試み－更に前進するには？－ A. Dote (KEK), Y. Kanada-En ’ yo （ KEK ）, H. Horiuchi (Kyoto univ.), Y. Akaishi (KEK), K. Ikeda (RIKEN) 1.Introduction.

RIKEN, March 2006: Mean field theories and beyond Peter Ring RIKEN, March 20, 2006 Technical University Munich RIKEN-06 Beyond Relativistic.

HL-3 May 2006Kernfysica: quarks, nucleonen en kernen1 Outline lecture (HL-3) Structure of nuclei NN potential exchange force Terra incognita in nuclear.

Chiral symmetry breaking and structure of quark droplets

Spectra of positive- and negative-energy nucleons in finite nuclei G. Mao 1,2, H. Stöcker 2, and W. Greiner 2 1) Institute of High Energy Physics Chinese.

Finite Nuclei and Nuclear Matter in Relativistic Hartree-Fock Approach Long Wenhui 1,2, Nguyen Van Giai 2, Meng Jie 1 1 School of Physics, Peking University,

1 Chiral Symmetry Breaking and Restoration in QCD Da Huang Institute of Theoretical Physics, Chinese Academy of

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

1 Nuclear Binding and QCD ( with G. Chanfray) Magda Ericson, IPNL, Lyon SCADRON70 Lisbon February 2008.

Relativistic chiral mean field model for nuclear physics (II) Hiroshi Toki Research Center for Nuclear Physics Osaka University.

Isospin effect in asymmetric nuclear matter (with QHD II model) Kie sang JEONG.

Role of tensor force in He and Li isotopes with tensor optimized shell model Hiroshi TOKI RCNP, Osaka Univ. Kiyomi IKEDA RIKEN Atsushi UMEYA RIKEN Takayuki.

Sigma model and applications 1. The linear sigma model (& NJL model) 2. Chiral perturbation 3. Applications.

The first systematic study of the ground-state properties of finite nuclei in the relativistic mean field model Lisheng Geng Research Center for Nuclear.

QUARK MATTER SYMMETRY ENERGY AND QUARK STARS Peng-cheng Chu ( 初鹏程 ) (INPAC and Department of Physics, Shanghai Jiao Tong University.

Effects of self-consistence violations in HF based RPA calculations for giant resonances Shalom Shlomo Texas A&M University.

XI ｔｈ International Conference on Quark Confinement and the Hadron Petersburg, Russia Philipp Gubler (RIKEN, Nishina Center) Collaborator:

Exotic Nuclei in Relativistic and Non-Relativistic Models Exotic Nuclei large isospin asymmetry - nuclei close to the drip lines - superheavy nuclei non-relativistic.

Variational Approach in Quantum Field Theories -- to Dynamical Chiral Phase Transition -- Yasuhiko TSUE Physica Division, Faculty of Science, Kochi University,

Hadron to Quark Phase Transition in the Global Color Symmetry Model of QCD Yu-xin Liu Department of Physics, Peking University Collaborators: Guo H., Gao.

Chiral condensate in nuclear matter beyond linear density using chiral Ward identity S.Goda (Kyoto Univ.) D.Jido （ YITP ） 12th International Workshop on.

Anthony W. Thomas Nuclei in the Laboratory and in the Cosmos 36 th Course - Erice : Sept 17 th 2014 Hyperons & the EoS of Dense Matter.

Relativistic mean field and RPA with negative energy states for finite nuclei Akihiro Haga, Hiroshi Toki, Setsuo Tamenaga, Yoko Ogawa, Research Center.

We construct a relativistic framework which takes into pionic correlations(2p-2h) account seriously from both interests: 1. The role of pions on nuclei.

Relativistic Description of the Ground State of Atomic Nuclei Including Deformation and Superfluidity Jean-Paul EBRAN 24/11/2010 CEA/DAM/DIF.

Masayasu Harada (Nagoya Univ.) based on M.H. and C.Sasaki, Phys.Rev.D74:114006,2006 at Chiral 07 (Osaka, November 14, 2007) see also M.H. and K.Yamawaki,

Role of vacuum in relativistic nuclear model A. Haga 1, H. Toki 2, S. Tamenaga 2 and Y. Horikawa 3 1. Nagoya Institute of Technology, Japan 2. RCNP Osaka.

Masayasu Harada (Nagoya Univ.) based on (mainly) M.H. and K.Yamawaki, Phys. Rev. Lett. 86, 757 (2001) M.H. and C.Sasaki, Phys. Lett. B 537, 280 (2002)

Extended Brueckner-Hartree-Fock theory in many body system - Importance of pion in nuclei - Hiroshi Toki (RCNP, KEK) In collaboration.

Modification of nucleon spectral function in the nuclear medium from QCD sum rules Collaborators: Philipp Gubler(ECT*), Makoto Oka Tokyo Institute of Technology.

NEW TRENDS IN HIGH-ENERGY PHYSICS (experiment, phenomenology, theory) Alushta, Crimea, Ukraine, September 23-29, 2013 Effects of the next-to-leading order.

Three-body force effect on the properties of asymmetric nuclear matter Wei Zuo Institute of Modern Physics, Lanzhou, China.

Operated by Jefferson Science Association for the U.S. Department of Energy Thomas Jefferson National Accelerator Facility Page 1 Check directly vs data.

And Mesons in Strange Hadronic Medium at Finite Temperature and Density Rahul Chhabra (Ph.D student) Department Of Physics NIT Jalandhar India In cooperation.

Helmholtz International Summer School, Dubna, 24 July 2008 Pion decay constant in Dense Skyrmion Matter Hee-Jung Lee ( Chungbuk Nat’l Univ.) Collaborators.

Toru T. Takahashi with Teiji Kunihiro ・ Why N*(1535)? ・ Lattice QCD calculation ・ Result TexPoint fonts used in EMF. Read the TexPoint manual before you.

1 11/20/13 21/11/2015 Jinniu Hu School of Physics, Nankai University Workshop on “Chiral forces and ab initio calculations” Nov. 20- Nov. 22,

11 Tensor optimized shell model with bare interaction for light nuclei In collaboration with Hiroshi TOKI RCNP, Osaka Univ. Kiyomi IKEDA RIKEN 19th International.

Beijing, QNP091 Matthias F.M. Lutz (GSI) and Madeleine Soyeur (Saclay) Irfu/SPhN CEA/ Saclay Irfu/SPhN CEA/ Saclay Dynamics of strong and radiative decays.

Satoru Sugimoto Kyoto University 1. Introduction 2. Charge- and parity-projected Hartree-Fock method (a mean field type model) and its application to sub-closed.

Nuclear Matter Density Dependence of Nucleon Radius and Mass and Quark Condensates in the GCM of QCD Yu-xin Liu Department of Physics, Peking University.

1  - mesic nuclei and baryon chiral symmetry in medium Hideko Nagahiro (Nara Women’s Univ.) collaborators: Daisuke Jido (Tech. Univ. Muenchen) Satoru.

Department of Physics, Sungkyunkwan University C. Y. Ryu, C. H. Hyun, and S. W. Hong Application of the Quark-meson coupling model to dense nuclear matter.

Denis Parganlija (Frankfurt U.) Finite-Temperature QCD Workshop, IST Lisbon Non-Strange and Strange Scalar Quarkonia Denis Parganlija In collaboration.

Accurate vacuum correction in finite nuclei A. Haga 1, H. Toki 1, S. Tamenaga 1, and Y. Horikawa 2 1.RCNP, Osaka Univ. 2.Juntendo Univ.

Relativistic descriptions of Nuclear magnetic moments Jie Meng 孟杰北京航空航天大学物理与核能工程学院 School of Physics and Nuclear Energy Engineering Beihang University.

Tensor interaction in Extended Brueckner-Hartree-Fock theory Hiroshi Toki (RCNP, Osaka) In collaboration with Yoko Ogawa.

Relativistic EOS for Supernova Simulations

The role of isospin symmetry in medium-mass N ~ Z nuclei

-Nucleon Interaction and Nucleon Mass in Dense Baryonic Matter

Tensor optimized shell model and role of pion in finite nuclei

Structure and dynamics from the time-dependent Hartree-Fock model

Structure of Mass Gap Between Two Spin Multiplets

mesons as probes to explore the chiral symmetry in nuclear matter

Role of Pions in Nuclei and Experimental Characteristics

Relativistic Chiral Mean Field Model for Finite Nuclei

Relativistic mean field theory and chiral symmetry for finite nuclei

Relativistic extended chiral mean field model for finite nuclei

Check directly vs data That is, apply new effective force directly to calculate nuclear properties using Hartree-Fock (as for usual well known force)

Kernfysica: quarks, nucleonen en kernen

Nuclear excitations in relativistic nuclear models

Effective Theory for Mesons

Pions in nuclei and tensor force

Variational Calculation for the Equation of State

Present status of bottom up model: sample works

Dilaton in Baryonic Matter

A possible approach to the CEP location

Institute of Modern Physics Chinese Academy of Sciences

Effects of the φ-meson on the hyperon production in the hyperon star

Presentation transcript:

0 Yoko Ogawa (RCNP/Osaka) Hiroshi Toki (RCNP/Osaka) Setsuo Tamenaga (RCNP/Osaka) Hong Shen (Nankai/China) Atsushi Hosaka (RCNP/Osaka) Satoru Sugimoto (RIKEN) Kiyomi Ikeda (RIKEN) Parity projected relativistic mean field theory for extended chiral sigma model

1 Introduction The purpose of this study is to understand the properties of finite nuclei by using a chiral sigma model with pion mean field within the relativistic mean field theory. Toki, Sugimoto and Ikeda demonstrate the occurrence of surface pion condensation. Prog. Theor. Phys. 108 (2002) 903. Chiral symmetry : Linear sigma model in hadron physics M. Gell-Mann and M. Levy, Nuovo Cimento 16(1960)705. Spontaneous chiral symmetry breaking Pion :Mediator of the nuclear force Y. Nambu and G. Jona-Lasinio, Phys. Rev. 122(1961)345. H. Yukawa, Proc. Phys.-Math.Soc. Jpn., 17(1935)48. Application of extended chiral sigma model for finite nuclei(N=Z even-even). Prog. Theor. Phys. 111(2004) 75. Problem of now framework Parity projection SummaryParity projected relativistic Hartree equations Contents

2 Lagrangian Linear Sigma Model

3 Extended Chiral Sigma Model Lagrangian(ECS) Dynamical mass generation term for omega meson J. Boguta, Phys. Lett. 120B(1983)34 Non- linear realization New nucleon field

4 Mean Field Equation Parity mixed single particle wave function Dirac equation Klein-Gordon equations

5  = fm -3 E/A-M = MeV K = 650 MeV g  = M / f   g  = m  / f   ~ m  = 777 MeV g  = Free parameter m  = 783MeV m  = 139 MeV M = 939 MeV f  = 93MeV Hadron property ECS TM1(RMF) Effective mass : M* = M + g   m*   =  m   + g   ~ Saturation property = (m  2 - m  2 ) / 2f    =  Non-linear coupling Character of the ECS model in nuclear matter Large incompressibility Small LS-force ~ 80 %

6 Finite Nuclei TM1(RMF) ECS model (without pion) ECS model (with pion) Y. Ogawa, H. Toki, S. Tamenaga, H. Shen, A. Hosaka, S. Sugimoto and K. Ikeda, Prog. Theor. Phys. Vol. 111, No. 1, 75 (2004)

7 Single Particle Spectrum Large incompressibility It is hard energetically to change a density. The state with large L bounds deeper. Anomalous pushed up 1s-state. N = 18 Without pionWith pion

8 The magic number appears at N = 18 instead of N = 20. Large incompressibility Anomalous pushed up 1s 1/2 state The effect of Dirac sea Parity projection We use the parity mixing intrinsic state in order to treat the pion mean field in the mean field theory because of the pseudovector(scalar) character of pion. We need to restore the parity symmetry and the variation after projection. The Problem and improvement of framework

9 Parity Projection Single particle wave function Total wave function h-state 2h-state 1p-1h 2p-2h H. Toki, S. Sugimoto, K. Ikeda, Prog. Theor. Phys. 108 (2002) 903.

10 N. Kaiser, S. Fritsch, W. Weise, Nucl. Phys. A697(2002)  2p-2hK = 255 MeV K = MeV _ Experiment

11 g 7/2 Fermi surface 56 Ni 40 Ca On the other hand, in 40 Ca case the j-upper state is far from Fermi level. In 56 Ni case the j-upper state is Fermi level 

12 Hamiltonian density Hamiltonian

13 Field operator for nucleon Creation operator for nucleon in a parity projected state  Parity projected wave function Total energy

14 Parity-projected relativistic mean field equations Nucleon part Variation after projection

15 Meson part We solve these self-consistent equations by using imaginary time step method.

16 Difficulties of relativistic treatment Total energy minimum variation condition gives difficulty to the relativistic treatment, because the relativistic theory involves the negative energy states. Summary We avoid this problem due to elimination of lower component. We however treat the equation which is mathematically equal to the Dirac equation. K. T. R. Davies, H. Flocard, S. Krieger, M. s. Weiss, Nucl. Phys. A342 (1980)111. P. G. reinhard, M. Rufa, J. Maruhn, W. Greiner, J. Friedrich, Z. Phys. A323, (1986)13. We derive the parity projected relativistic Hartree equations. We show the problem in now framework of ECS model. Magic number at N = 20 ? Prediction of 0- state Large incompressibility.Magic number at N = 20.