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

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Presentation transcript:

Extended Brueckner-Hartree-Fock theory in many body system - Importance of pion in nuclei - Hiroshi Toki (RCNP, KEK) In collaboration with Yoko Ogawa (RCNP) Jinniu Hu (RCNP) Kaori Horii (RCNP) Takayuki Myo (Osaka Inst. of Technology) Kiyomi Ikeda (RIKEN)

Pion is important in Nuclear Physics ！ Yukawa （１９３４） predicted pion as a mediator of nuclear interaction to form nucleus Meyer-Jansen （１９４９） introduced shell model ー beginning of Nuclear Physics Nambu （１９６０） introduced the chiral symmetry and its breaking produced mass and the pion as pseudo- scalar particle

Shell model (Meyer-Jensen) Phenomenological Strong spin-orbit interaction added by hand Magic number 2,8,20,28,50, Harmonic oscillator

The importance of pion is clear in deuteron Deuteron (1 + ) NN interaction S=1 and L=0 or 2

Variational calculation of few body system with NN interaction C. Pieper and R. B. Wiringa, Annu. Rev. Nucl. Part. Sci.51(2001) VMC+GFMC V NNN Fujita-Miyazawa Relativistic Pion is keyHeavy nuclei (Super model)

Pion is important in nucleus ８０％ of attraction is due to pion Tensor interaction is particularly important Pion Tensor spin-spin

Halo structure in 11 Li Deuteron structure in shell model is produced by 2p-2h states Deuteron wave function Myo Kato Toki Ikeda PRC(2008) (Tanihata..)

Pairing-blocking : K.Kato,T.Yamada,K.Ikeda,PTP101(‘99)119, Masui,S.Aoyama,TM,K.Kato,K.Ikeda,NPA673('00)207. TM,S.Aoyama,K.Kato,K.Ikeda,PTP108('02)133, H.Sagawa,B.A.Brown,H.Esbensen,PLB309('93)1.

Tensor optimized shell model （ TOSM ） Myo, Toki, Ikeda, Kato, Sugimoto, PTP 117 (2006) 0p-0h + 2p-2h Energy variation (size parameter) GcGc

11 Li G.S. properties (S 2n =0.31 MeV) Tensor +Pairing Simon et al. P(s 2 ) RmRm E(s 2 )-E(p 2 ) [MeV] Pairing interaction couples (0p) 2 and (1s) 2 states.

Unitary Correlation Operator Method H. Feldmeier, T. Neff, R. Roth, J. Schnack, NPA632(1998)61 short-range correlator Bare Hamiltonian Shift operator depending on the relative distance r (UCOM)

4 He with UCOM

TOSM+UCOM with AV8’ T V LS E VCVC VTVT Few body Calculation (Kamda et al) (Myo Toki Ikeda)

Y0Y0 Y2Y2 +

TOSM should be used for nuclear many body problem 2p-2h excitation is essential for treatment of pion G.S. Spin-saturated The spin flipped states are already occupied by other nucleons. Pauli forbidden

(2011) HF state cannot handle the tensor interaction

Total energy Energy variation

Variation with HF state We can solve finite nuclei by solving the above equation.

EBHF equation Similar to BHF equation

Feshbach projection method

Comparison to BHF theory There appears |C 0 | 2. |C 0 | 2 is not normalized to 1.

Nucl. Phys (2011) Direct terms only

Relativistic chiral mean field model The difference between 12 C and 16 O is 1.5 MeV/N. The difference comes from low pion spin states (J<3). This is the Pauli blocking effect. P 3/2 P 1/2 C O S 1/2 Pion energy Pion tensor provides large attraction for 12 C O C Pion contribution Individual contribution O C

Renaissance in Nuclear Physics by pion We have a EBHF theory with pion Unification of hadron and nuclear physics Pion is the main player ー Pion renaissance High momentum components are produced by pion （ Tensor interaction ）ー Nuclear structure renaissance Nuclear Physics is truly interesting!!

Monden

Relativistic Brueckner-Hartree-Fock theory Brockmann-Machleidt (1990) U s ~ -400MeV U v ~ 350MeV relativity RBHF Non-RBHF

Important experimental data

Deeply bound pionic atom Toki Yamazaki, PL(1988) Prediction Found by (d, 3 GSI Itahashi, Hayano, Yamazaki.. Z. Phys.(1996), PRL(2004) Physics : isovector s-wave

Suzuki, Hayano, Yamazaki.. PRL(2004) Optical model analysis for the deeply bound state.

Nuclear structure caused by pion ２ p− ２ h excitation is ２０％ High momentum components Low momentum components （ Shell model ） are reduced by ２０ %

RCNP experiment (high resolution) Y. Fujita et al., E.Phys.J A13 (2002) 411 H. Fujita et al., PRC Not simple Giant GT

16 O (p,d) E p = 198 MeV Θ d = 10° 16 O (p,d) E p = 295 MeV Θ d = 10° 16 O (p,d) E p = 392 MeV Θ d = 10° 15 O Level scheme 1/ Ong, Tanihata et al

Relative Cross Section a) J. L. Snelgrove et al., PR187, 1246(1969) b) J.K.P. Lee et al., NPA106, 357(1968) c) G.R. Smith et al., PRC30, 593(1984) Ex[MeV] J  gs 0.0 1/ /2 +, 5/ / /2 +, 5/ / / / /2 +,1/2 +,(1/2) (3/2) +,5/ (9/2 + ),(3/2 - ),(3/2) / /2 -, 5/ / / gs c)c)a) Incident proton energy [MeV] relative cross section  1 /  gs  2 /  gs  4 /  gs  6 /  gs  12 /  gs This work b)b)

Centrifugal potential pushes away the L=2 wave function The property of tensor interaction