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Table of contents 1. Motivation 2. Formalism (3-body equation) 3. Results (KNN resonance state) 4. Summary Table of contents 1. Motivation 2. Formalism.

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Presentation on theme: "Table of contents 1. Motivation 2. Formalism (3-body equation) 3. Results (KNN resonance state) 4. Summary Table of contents 1. Motivation 2. Formalism."— Presentation transcript:

1 Table of contents 1. Motivation 2. Formalism (3-body equation) 3. Results (KNN resonance state) 4. Summary Table of contents 1. Motivation 2. Formalism (3-body equation) 3. Results (KNN resonance state) 4. Summary

2 Kaon absorption?? (Magas et al.) Kaon absorption?? (Magas et al.) 1. Motivation

3 Our Investigation We investigate the possible We investigate the possible [KNN] (I=1/2,J=0) 3-body resonance state. [KNN] (I=1/2,J=0) 3-body resonance state. P P K-K- K - pp system S=-1, B=2, Q=+1 We consider s-wave 3-body KNN state. We consider s-wave 3-body KNN state. We expect most strong attractive interaction We expect most strong attractive interaction in this configure. in this configure. L=0 (s-wave interaction) -> Coupled channel Faddeev equation Solve -> KNN 3-body resonance Find

4 Meson-Baryon interaction 2. Formalism We employ the dipole form factor. Cut-off parameter -> fit scattering length (Kaonic hydrogen, Martin’s analysis) Chiral effective Lagrangian

5 AGS equation for 3-body amplitude Eigenvalue equation for Fredholm kernel Pole of 3-body amplitude

6 spectator energy 3. Numerical Results KN amplitude bellow threshold W KN (MeV) 2-body T-matrix in the 3-body system 2-body T-matrix in the 3-body system :spectator energy How this attractive KN interaction contributes to 3-body binding system is determined by solving dynamical 3-body eq. directly!!

7 -44.9-i21.0 (MeV) -59.2-i15.9 (MeV)

8 4. Summary The pole position strongly depends on KN interaction. The pole position strongly depends on KN interaction. -> form factor (dipole -> monopole) -> form factor (dipole -> monopole) -> explicit resonance model (3-quark ) -> explicit resonance model (3-quark ) Effects of kaon absorption (p-wave interaction) Effects of kaon absorption (p-wave interaction) We solve 3-body equation directly. We can find the resonance pole We can find the resonance pole in the and energy plane. in the and energy plane. (W pole = -59.2-i15.9 MeV using relativistic kinematics) (W pole = -59.2-i15.9 MeV using relativistic kinematics) Future works

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10 φ : Meson field, B : Baryon field = 2-body Meson-Baryon Potential

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12 Yamaguchi type NN interaction attractive repulsive We take an attractive term only. phase shift (degree) T Lab Strong attraction!? repulsive attractive attractive only

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14 Formal solution of AGS equation Fredholm type kernel Eigenvalue equation for Fredholm kernel Formal solution for 3-boby amplitude

15 ・ Pearce and Gibson PRC 40 902. 2-body scattering term Complex q plane Pole of scattering state Pole of resonance state = Physical branch Unphysical branch Singularity of tau

16 -> Logarithmically singularity 1 particle exchange term


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