NSR Query Results
Output year order : Descending NSR database version of April 25, 2024. Search: Author = M.Ishikawa Found 25 matches. 2021II01 Nucl.Instrum.Methods Phys.Res. A986, 164727 (2021) T.Iida, K.Mizukoshi, T.Ohata, T.Uehara, T.Batpurev, K.Fushimi, R.Hazama, M.Ishikawa, H.Kakubata, K.Kanagawa, S.Katagiri, B.T.Khai, T.Kishimoto, X.Li, T.Maeda, K.Matsuoka, K.Morishita, M.Moser, K.Nakajima, M.Nomachi, I.Ogawa, M.Shokati, K.Suzuki, Y.Takemoto, Y.Takihira, Y.Tamagawa, K.Tetsuno, M.Tozawa, V.T.T.Trang, S.Umehara, S.Yoshida The energy calibration system for CANDLES using (n, γ) reaction NUCLEAR REACTIONS 28Si, 56Fe, 58Ni(n, γ), E<2.1 MeV; measured reaction products, Eγ, Iγ; deduced γ-ray energies and intensities, calibration procedures.
doi: 10.1016/j.nima.2020.164727
2021YO01 Ann.Nucl.Energy 154, 108100 (2021) Great achievements of M. Salvatores for nuclear data adjustment study with use of integral experiments
doi: 10.1016/j.anucene.2020.108100
2018CH12 Nucl.Data Sheets 148, 189 (2018) M.B.Chadwick, R.Capote, A.Trkov, M.W.Herman, D.A.Brown, G.M.Hale, A.C.Kahler, P.Talou, A.J.Plompen, P.Schillebeeckx, M.T.Pigni, L.Leal, Y.Danon, A.D.Carlson, P.Romain, B.Morillon, E.Bauge, F.-J.Hambsch, S.Kopecky, G.Giorginis, T.Kawano, J.Lestone, D.Neudecker, M.Rising, M.Paris, G.P.A.Nobre, R.Arcilla, O.Cabellos, I.Hill, E.Dupont, A.J.Koning, D.Cano-Ott, E.Mendoza, J.Balibrea, C.Paradela, I.Duran, J.Qian, Z.Ge, T.Liu, L.Hanlin, X.Ruan, W.Haicheng, M.Sin, G.Noguere, D.Bernard, R.Jacqmin, O.Bouland, C.De Saint Jean, V.G.Pronyaev, A.V.Ignatyuk, K.Yokoyama, M.Ishikawa, T.Fukahori, N.Iwamoto, O.Iwamoto, S.Kunieda, C.R.Lubitz, M.Salvatores, G.Palmiotti, I.Kodeli, B.Kiedrowski, D.Roubtsov, I.Thompson, S.Quaglioni, H.I.Kim, Y.O.Lee, U.Fischer, S.Simakov, M.Dunn, K.Guber, J.I.Marquez Damian, F.Cantargi, I.Sirakov, N.Otuka, A.Daskalakis, B.J.McDermott, S.C.van der Marck CIELO Collaboration Summary Results: International Evaluations of Neutron Reactions on Uranium, Plutonium, Iron, Oxygen and Hydrogen NUCLEAR REACTIONS 1H, 16O, 56Fe, 235,238U, 239Pu(n, X), E<20 MeV; analyzed available data; calculated σ, σ(θ), σ(θ, E).
doi: 10.1016/j.nds.2018.02.003
2015YO01 Nucl.Data Sheets 123, 97 (2015) Use and Impact of Covariance Data in the Japanese Latest Adjusted Library ADJ2010 Based on JENDL-4.0
doi: 10.1016/j.nds.2014.12.017
2014CH24 Nucl.Data Sheets 118, 1 (2014) M.B.Chadwick, E.Dupont, E.Bauge, A.Blokhin, O.Bouland, D.A.Brown, R.Capote, A.Carlson, Y.Danon, C.De Saint Jean, M.Dunn, U.Fischer, R.A.Forrest, S.C.Frankle, T.Fukahori, Z.Ge, S.M.Grimes, G.M.Hale, M.Herman, A.Ignatyuk, M.Ishikawa, N.Iwamoto, O.Iwamoto, M.Jandel, R.Jacqmin, T.Kawano, S.Kunieda, A.Kahler, B.Kiedrowski, I.Kodeli, A.J.Koning, L.Leal, Y.O.Lee, J.P.Lestone, C.Lubitz, M.MacInnes, D.McNabb, R.McKnight, M.Moxon, S.Mughabghab, G.Noguere, G.Palmiotti, A.Plompen, B.Pritychenko, V.Pronyaev, D.Rochman, P.Romain, D.Roubtsov, P.Schillebeeckx, M.Salvatores, S.Simakov, E.Sh.Soukhovitskii, J.C.Sublet, P.Talou, I.Thompson, A.Trkov, R.Vogt, S.van der Marck The CIELO Collaboration: Neutron Reactions on 1H, 16O, 56Fe, 235, 238U, and 239Pu COMPILATION 1H, 16O, 56Fe, 235,238U, 239Pu(n, x), E≈0-20 MeV; analyzed available data on σ, neutron multiplicity, criticality using ENDF/B-VII.1, JENDL-4.0, JEFF-3.1, ROSFOND 2010, CENDL-3.1, EAF-2010 evaluated nuclear libraries, Atlas of Neutron Resonances, Neutron Cross Section Standards evaluations; deduced recommendations for CIELO library, parameters, Maxwellian-averaged, thermal, californium σ, Westcott factors, resonance integrals. Compared with available data.
doi: 10.1016/j.nds.2014.04.002
2014DU08 Nucl.Data Sheets 120, 264 (2014) E.Dupont, M.B.Chadwick, Y.Danon, C.De Saint Jean, M.Dunn, U.Fischer, R.A.Forrest, T.Fukahori, Z.Ge, H.Harada, M.Herman, M.Igashira, A.Ignatyuk, M.Ishikawa, O.Iwamoto, R.Jacqmin, A.C.Kahler, T.Kawano, A.J.Koning, L.Leal, Y.O.Lee, R.McKnight, D.McNabb, R.W.Mills, G.Palmiotti, A.Plompen, M.Salvatores, P.Schillebeeckx Working Party on International Nuclear Data Evaluation Cooperation (WPEC)
doi: 10.1016/j.nds.2014.07.063
2014FU05 Nucl.Data Sheets 118, 405 (2014) M.Fukushima, M.Ishikawa, K.Numata, T.Jin, T.Kugo Benchmark Calculations for Reflector Effect in Fast Cores by Using the Latest Evaluated Nuclear Data Libraries
doi: 10.1016/j.nds.2014.04.092
2014SA35 Nucl.Data Sheets 118, 38 (2014) M.Salvatores, G.Palmiotti, G.Aliberti, P.Archier, C.De Saint Jean, E.Dupont, M.Herman, M.Ishikawa, T.Ivanova, E.Ivanov, S.-J.Kim, I.Kodeli, G.Manturov, R.McKnight, S.Pelloni, C.Perfetti, A.J.M.Plompen, B.T.Rearden, D.Rochman, K.Sugino, A.Trkov, W.Wang, H.Wu, W.-S.Yang Methods and Issues for the Combined Use of Integral Experiments and Covariance Data: Results of a NEA International Collaborative Study NUCLEAR REACTIONS 238U(n, n'), E=100 eV-10 MeV;239,241Pu(n, F), E=100 eV-10 MeV; calculated relative σ uncertaintites. 239Pu(n, γ), E=100 ev-10 MeV; calculated parameters uncertainty.
doi: 10.1016/j.nds.2014.04.005
2011CH01 J.Nucl.Sci.Technol.(Tokyo) 48, 172 (2011) G.Chiba, K.Okumura, K.Sugino, Y.Nagaya, K.Yokoyama, T.Kugo, M.Ishikawa, S.Okajima JENDL-4.0 Benchmarking for Fission Reactor Applications
doi: 10.3327/jnst.48.172
2011OK02 J.Korean Phys.Soc. 59, 1135s (2011) K.Okumura, K.Sugino, G.Chiba, Y.Nagaya, K.Yokoyama, T.Kugo, M.Ishikawa, S.Okajima JENDL-4.0 Integral Testing for Fission Systems
doi: 10.3938/jkps.59.1135
2011SU26 J.Korean Phys.Soc. 59, 1357s (2011) K.Sugino, M.Ishikawa, K.Yokoyama, Y.Nagaya, G.Chiba, T.Hazama, T.Kugo, K.Yokoyama, T.Iwai, T.Jin Development of a Unified Cross-Section Set ADJ2010 Based on Adjustment Technique for Fast Reactor Core Design
doi: 10.3938/jkps.59.1357
2011YA20 J.Korean Phys.Soc. 59, 1298s (2011) N.Yamano, T.Yoshida, K.Nakajima, M.Ishikawa, K.Shibata, K.Suyama, K.Okumura, O.Iwamoto, M.Uematsu, Y.Tahara Quality Management System Proposed to JENDL Evaluation Project
doi: 10.3938/jkps.59.1298
2008IS06 Nucl.Data Sheets 109, 2778 (2008) Application of Covariances to Fast Reactor Core Analysis
doi: 10.1016/j.nds.2008.11.009
2008OT01 J.Nucl.Sci.Technol.(Tokyo) 45, 195 (2008) N.Otuka, A.Zukeran, H.Takano, G.Chiba, M.Ishikawa Covariance Analyses of Self-Shielding Factor and Its Temperature Gradient for Uranium-238 Neutron Capture Reaction
doi: 10.3327/jnst.45.195
2002SH40 J.Nucl.Sci.Technol.(Tokyo) 39, 1125 (2002) K.Shibata, T.Kawano, T.Nakagawa, O.Iwamoto, J.Katakura, T.Fukahori, S.Chiba, A.Hasegawa, T.Murata, H.Matsunobu, T.Ohsawa, Y.Nakajima, T.Yoshida, A.Zukeran, M.Kawai, M.Baba, M.Ishikawa, T.Asami, T.Watanabe, Y.Watanabe, M.Igashira, N.Yamamuro, H.Kitazawa, N.Yamano, H.Takano Japanese Evaluated Nuclear Data Library Version 3 Revision-3: JENDL-3.3
doi: 10.1080/18811248.2002.9715303
2000AJ02 Phys.Rev.Lett. 84, 4052 (2000) S.Ajimura, K.Ikeda, M.Ishikawa, T.Kishimoto, A.Okusu, N.Shinkai, Y.Tanaka, H.Ejiri, T.Nakano, K.Manabe, T.Nagae, H.Noumi, M.Sekimoto, T.Shibata, O.Hashimoto, K.Maeda, T.Takahashi, T.Hasegawa, H.Bhang, Y.D.Kim, H.Park, M.Youn Asymmetry in the Nonmesonic Weak Decay of Polarized Λ5He Hypernuclei NUCLEAR REACTIONS 6Li(π+, K+), E not given; measured pion, proton spectra, asymmetry following hypernucleus decay. 5He deduced hypernucleus asymmetry parameter for nonmesonic decay.
doi: 10.1103/PhysRevLett.84.4052
2000AJ03 Nucl.Phys. A663-664, 493c (2000) S.Ajimura, H.Bhang, H.Ejiri, T.Hasegawa, O.Hashimoto, M.Ishikawa, K.Ikeda, Y.Kim, T.Kishimoto, K.Maeda, K.Manabe, T.Nagae, T.Nakano, H.Noumi, A.Okusu, H.Park, M.Sekimoto, T.Shibata, N.Shinkai, T.Takahashi, Y.Tanaka, M.Youn Asymmetry in Nonmesonic Decay of Polarized Λ5He Hypernucleus NUCLEAR REACTIONS 6Li(π+, K+p), E at 1.05 GeV/c; measured excitation energy spectra, asymmetry; deduced polarized hypernucleus decay features.
doi: 10.1016/S0375-9474(99)00639-9
2000AJ04 Nucl.Phys. A670, 285c (2000) S.Ajimura, H.Bhang, H.Ejiri, T.Hasegawa, O.Hashimoto, M.Ishikawa, K.Ikeda, Y.Kim, T.Kishimoto, K.Maeda, K.Manabe, T.Nagae, T.Nakano, H.Noumi, A.Okusu, H.Park, M.Sekimoto, T.Shibata, N.Shinkai, T.Takahashi, Y.Tanaka, M.Youn Asymmetric Weak Decay of Polarized Hypernuclei NUCLEAR REACTIONS 6Li(π+, K+p), E at 1.05 GeV/c; measured excitation energy spectra, asymmetry; deduced polarized hypernucleus decay features.
doi: 10.1016/S0375-9474(00)00114-7
1998AJ01 Phys.Rev.Lett. 80, 3471 (1998) S.Ajimura, M.Ishikawa, K.Ikeda, T.Kishimoto, A.Okusu, N.Shinkai, Y.Tanaka, H.Ejiri, T.Nakano, T.Nagae, H.Noumi, K.Manabe, M.Sekimoto, T.Shibata, O.Hashimoto, K.Maeda, T.Takahashi, T.Hasegawa, H.Bhang, H.Park, Y.Kim, M.Youn, T.Motoba, K.Itonaga Polarization of (Λ)5He Produced by the (π+, K+) Reaction NUCLEAR REACTIONS 6Li(π+, K+), (π+, K+p), E at 1.05 GeV/c; measured excitation energy spectra, asymmetry; deduced 5He hypernucleus formation, polarization.
doi: 10.1103/PhysRevLett.80.3471
1995BB18 Nucl.Instrum.Methods Phys.Res. A366, 354 (1995) M.Baba, S.Matsuyama, M.Ishikawa, S.Chiba, T.Sakase, N.Hirakawa Correction of Double-Differential Neutron Emission Data for Sample-Dependent Effects NUCLEAR REACTIONS Mo, 12C(n, xn), E=14 MeV; 93Nb(n, xn), E=18 MeV; measured σ(θn, En). Data correction method with sample size effects, contaminant source neutrons caused sample-dependent background.
doi: 10.1016/0168-9002(95)00616-8
1995KI05 Nucl.Phys. A585, 205c (1995) T.Kishimoto, S.Ajimura, H.Ejiri, K.Ikeda, M.Ishikawa, T.Nakano, A.Okusu, N.Shinkai, Y.Tanaka, T.Hasegawa, O.Hashimoto, T.Nagae, M.Sekimoto, T.Shibata, H.Noumi, K.Manabe, K.Maeda, T.Takahashi, H.Bhang, H.Park, M.Youn Study of (Lambda)N → NN Processes in Polarized 5He(Lambda) NUCLEAR REACTIONS 6Li(π+, K+), E at 1.05 GeV/c; measured excitation energy spectra, 5He(Lambda) hypernucleus decay particles asymmetry; deduced non-mesonic decay associated dominant mechanism.
doi: 10.1016/0375-9474(94)00566-6
1994KI19 Nucl.Phys. A577, 263c (1994) T.Kishimoto, S.Ajimura, H.Ejiri, K.Ikeda, M.Ishikawa, T.Nakano, A.Okusu, N.Shinkai, Y.Tanaka, T.Hasegawa, O.Hashimoto, T.Nagae, M.Sekimoto, T.Shibata, H.Noumi, K.Manabe, K.Maeda, T.Takahashi, H.Bhang, H.Park, M.Youn Spin Polarization and Weak Decay of Polarized (Lambda) Hypernuclei NUCLEAR REACTIONS 12C(π+, K+), E at 1.05 GeV/c; analyzed data; deduced hypernucleus nonmesonic decay asymmetry vs polarization. Discussed 6Li(π+, K+p) reaction.
doi: 10.1016/0375-9474(94)90865-6
1983IS10 Phys.Rev. C28, 1884 (1983) M.Ishikawa, S.Seki, K.Furuno, Y.Tagishi, M.Sawada, T.Sugiyama, K.Matsuda, T.Murayama, N.X.Dai, J.Sanada, Y.Koike 4He(d(pol), p)n4He Reaction at 12 and 21 MeV Deuteron Energy NUCLEAR REACTIONS 4He(polarized d, p), E=12, 21 MeV; measured σ(θ, Ep), iT11(θ), T20(θ), T21(θ), T22(θ); deduced effective interaction observable dependence. Faddeev formalism.
doi: 10.1103/PhysRevC.28.1884
1983SA05 Phys.Rev. C27, 1932 (1983) M.Sawada, S.Seki, K.Furuno, Y.Tagishi, Y.Nagashima, J.Schimizu, M.Ishikawa, T.Sugiyama, L.S.Chuang, W.Gruebler, J.Sanada, Y.Koike, Y.Taniguchi Complete Set of First-Order Polarization Observables in Nucleon-Deuteron Elastic Scattering near 20 MeV Deuteron Energy NUCLEAR REACTIONS 2H(polarized p, p), E=11.1 MeV; measured σ(θ), analyzing power vs θ. 1H(polarized d, d), E=17, 20, 22.2 MeV; measured iT11(θ), T20(θ), T21(θ), T22(θ). Faddeev calculations.
doi: 10.1103/PhysRevC.27.1932
1982IS06 J.Phys.Soc.Jpn. 51, 1327 (1982) M.Ishikawa, S.Seki, K.Furuno, Y.Tagishi, M.Sawada, T.Sugiyama, K.Matsuda, J.Sanada, Y.Koike Tensor Analyzing Powers for Deuteron Breakup Reaction in d + α System NUCLEAR REACTIONS 4He(polarized d, np), E=12, 21 MeV; measured iT11(θ), T20(θ), T21(θ), T22(θ); deduced tensor force importance. Kinematically incomplete geometry. Faddeev formalism.
doi: 10.1143/JPSJ.51.1327
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