NSR Query Results
Output year order : Descending NSR database version of May 1, 2024. Search: Author = M.Yonezawa Found 12 matches. 1996KA31 Phys.Rev. D53, 4838 (1996) M.Kawasaki, T.Maehara, M.Yonezawa Quantitative Test of the Generalized Geometrical Scaling Hypothesis for Elastic pp and (p-bar)p Scattering NUCLEAR REACTIONS 1H(p, p), (p-bar, p-bar), E=high; analyzed data; deduced geometrical scaling hypothesis validity related features.
doi: 10.1103/PhysRevD.53.4838
1995KA12 Phys.Lett. 348B, 623 (1995) M.Kawasaki, T.Maehara, M.Yonezawa The Elastic (p-bar)p Differential Cross Section Measurements at the CERN Sp(p-bar)S and the Real Part of the Scattering Amplitude NUCLEAR REACTIONS 1H(p-bar, p-bar), E=high; analyzed differential σ data; deduced forward scattering amplitude real to imaginary part ratio.
doi: 10.1016/0370-2693(95)00196-R
1990HI10 Prog.Theor.Phys.(Kyoto) 84, 941 (1990) N.Hiroshige, M.Kawasaki, W.Watari, M.Yonezawa Partial-Wave Amplitudes of Elastic πd Scattering NUCLEAR REACTIONS 2H(π, π), E=117-325 MeV; analyzed data; deduced 3P2, 3D3, S-wave matrix element moduli.
doi: 10.1143/ptp/84.5.941
1985HI01 Phys.Lett. 150B, 41 (1985) N.Hiroshige, W.Watari, K.Takabayashi, M.Yonezawa The Dibaryon Resonance in Pion-Deuteron Scattering and the Standard Theory for the A = 2 System NUCLEAR REACTIONS 2H(π, π), E ≈ 2-2.25 GeV; calculated reaction partial wave amplitudes; deduced dibaryon resonance role. Standard two-nucleon model, Faddeev formalism.
doi: 10.1016/0370-2693(85)90133-9
1984HI14 Prog.Theor.Phys.(Kyoto) 72, 146 (1984) N.Hiroshige, M.Kawasaki, K.Takabayashi, W.Watari, M.Yonezawa Analysis of the Dibaryon Resonances with J(π) = 2+ and 3- by a Three-Channel (pp, NΔ, πd) K-Matrix Method NUCLEAR REACTIONS 1H(p, p), (p, π), 2H(π, π), E ≈ resonance; analyzed phase shifts; deduced dibaryon resonances, J, π.
1984HI15 Prog.Theor.Phys.(Kyoto) 72, 1146 (1984) N.Hiroshige, W.Watari, M.Yonezawa Partial-Wave Amplitudes of pp - π+d Process from Its Threshold to T(p)(L)=810 MeV NUCLEAR REACTIONS 1H(p, π+), E=threshold-810 MeV; analyzed phase shifts; deduced partial wave amplitude.
doi: 10.1143/PTP.72.1146
1982AK02 Prog.Theor.Phys.(Kyoto) 67, 554 (1982) M.Akemoto, M.Matsuda, H.Suemitsu, M.Yonezawa On the Phase-Shift Solution in the Diproton Resonance Region: P(L) = 1.2 ≈ 1.7 GeV/c NUCLEAR REACTIONS 1H(p, p), E at 1.2, 1.3, 1.4, 1.5, 1.7 GeV/c; analyzed data; deduced uniqueness, stability of phase shift solution.
doi: 10.1143/PTP.67.554
1982HI08 Prog.Theor.Phys.(Kyoto) 68, 327 (1982) N.Hiroshige, W.Watari, M.Yonezawa Phase Shift Analysis of π - d Elastic Scattering in the Momentum Region p(π)(lab) = 245 MeV/c ≈ 539 MeV/c NUCLEAR REACTIONS 2H(π, π), E at 245-539 MeV/c; calculated σ(θ), recoil deuteron tensor polarization vs θ. Phase shift analysis.
doi: 10.1143/PTP.68.327
1982HI15 Prog.Theor.Phys.(Kyoto) 68, 2074 (1982) N.Hiroshige, W.Watari, M.Yonezawa Partial Wave Analysis of pp → π+d Reaction in the Energy Region T(p)(lab) ≤ 810 MeV NUCLEAR REACTIONS 1H(p, π+), (polarized p, π+), E ≤ 800 MeV; analyzed σ(θ), total(σ), analyzing power, recoil deuteron polarization data. Partial wave analysis.
doi: 10.1143/PTP.68.2074
1980KA33 Prog.Theor.Phys.(Kyoto) 64, 2144 (1980) A Partial-Wave Analysis of p + p → π+ + d Reaction from Threshold to T(L)=578 MeV NUCLEAR REACTIONS 1H(polarized p, d), (p, d), E=thermal-578 MeV; analyzed σ(θ), polarization, vector, tensor analyzing power data; deduced transition amplitudes. Partial wave anaysis.
doi: 10.1143/PTP.64.2144
1972FU11 Nucl.Phys. A193, 285 (1972) S.Furuichi, H.Suemitsu, M.Yonezawa, W.Watari The Kantor Amplitudes of Nucleon-Nucleon Scattering below 500 MeV
doi: 10.1016/0375-9474(72)90253-9
1971FU04 Nucl.Phys. A165, 211 (1971) S.Furuichi, H.Suemitsu, M.Yonezawa, W.Watari Analysis of the Kantor Amplitudes and Recent Low-Energy Proton-Proton Scattering Experiments NUCLEAR REACTIONS 1H(p, p), E=25-50 MeV; calculated phase shifts.
doi: 10.1016/0375-9474(71)90159-X
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