Matsuyanagi Kenichi | Department Of Physics Graduate School Of Science Kyoto University
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概要
関連著者
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Matsuyanagi Kenichi
Department Of Physics Graduate School Of Science Kyoto University
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松柳 研一
Theoretical Nuclear Physics Laboratory Riken Nishina Center:yukawa Institute For Theoretical Physics
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MATSUYANAGI Kenichi
Department of Physics, Graduate School of Science, Kyoto University
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Matsuyanagi Kenichi
Theoretical Nuclear Physics Laboratory Riken Nishina Center
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MATSUYANAGI Kenichi
Department of Physics, Kyoto University
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松柳 研一
京都大学大学院理学研究科
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松柳 研一
理研仁科セ
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Shimizu Yoshifumi
Department Of Physics Graduate School Of Sciences Kyushu University
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NAKATSUKASA Takashi
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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Kuriyama Atsushi
Department Of Physics Kyushu University
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Kuriyama Atsushi
Department Of Physics Kyoto University
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Nakatsukasa Takashi
Theoretical Nuclear Physics Laboratory Riken Nishina Center
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Matsuo Masayuki
Department Of Materials Science Nagoya Institute Of Technology
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NAKATSUKASA Takashi
Physics Department, Tohoku University
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Nakatsukasa T
Physics Department Tohoku University
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NAKATSUKASA Takashi
Institute of Physics and Center for Computational Science, University of Tsukuba
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MATSUO Masayuki
Department of Physics, Niigata University
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Mizutori Shoujirou
Department Of Human Science Kansai Women's College
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Arita Ken-ichiro
Department Of Physics Kyoto University
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Nakatsukasa Takashi
Institute of Physics & Center for Computational Sciences, University of Tsukuba
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Matsuo M
Department Of Physics Niigata University
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MIZUTORI Shoujirou
Department of Physics, Kyoto University
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MARUMORI Toshio
Institute of Physics, University of Tsukuba
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Marumori Toshio
Institute For Nuclear Study University Of Tokyo
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MIZUTORI Shoujirou
Institute for Nuclear Study, University of Tokyo
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Suzuki Toru
Institut Fur Kernphysik Kernforschungsanlage Julich
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Suzuki Toru
Department Of Physics Kyoto University
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SHIMIZU Yoshifumi
Department of Physics, Kyushu University
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Yamagami Masayuki
Theoretical Nuclear Physics Laboratory Riken Nishina Center
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Yamagami Masayuki
Department Of Physics Graduate School Of Science Kyoto University
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Matsuo Masayuki
Graduate School Of Science And Technology Niigata University
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Matsuo Masayuki
Department Of Physics Faculty Of Science Niigata University
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HINOHARA Nobuo
Department of Physics, Graduate School of Science, Kyoto University
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YAMAGAMI Masayuki
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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ARITA Kenichiro
Department of Physics, Nagoya Institute of Technology
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Suzuki Toru
Department Of Food Science And Technology Tokyo University Of Marine Science And Technology
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Suzuki Toru
Department Of Biosphere And Environmental Sciences Faculty Of Environment Systems Rakuno Gakuen Univ
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ARITA Ken-ichiro
Department of Physics, Nagoya Institute of Technology
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ARITA Ken-ichiro
Department of Physics, Kyoto University
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HINOHARA Nobuo
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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Hlnohara Nobuo
Theoretical Nuclear Physics Laboratory Riken Nishina Center
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KOBAYASI Masato
Department of Physics, Graduate School of Science, Kyoto University
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Yoshida Kenichi
Theoretical Nuclear Physics Laboratory Riken Nishina Center
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YAMAGAMI Masayuki
Heavy Ion Nuclear Physics Laboratory, RIKEN
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Fuyuki Masahiko
Department Of Physics Kyoto University
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Shimizu Y
Department Of Physics Kyushu University
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Suzuki Toru
Department Of Cardiology Sakakibara Heart Institute
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Yoshida Kenichi
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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HINOHARA Nobuo
Department of Physics and Astronomy, University of North Carolina:Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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FUYUKI Masahiko
Department of Physics, Kyoto University : Department of Physics, Osaka University
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FUYUKI Masahiko
Department of Physics, Kyoto Univeristy
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Suzuki Toru
Department of Applied Electronics, Faculty of Industrial Science and Technology, Tokyo University of Science, 2641 Yamazaki, Noda, Chiba 278-8510, Japan
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Suzuki Toru
Department Of Ubiquitous Preventive Medicine Graduate School Of Medicine The University Of Tokyo
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Arita Ken-ichiro
Department Of Physics Nagoya Institute Of Technology
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OKAMOTO Ryoji
Department of Physics, Faculty of Engineering, Kyushu Institute of Technology
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FUYUKI Masahiko
Department of Physics, Kyoto University
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SUGITA Ayumu
Department of Physics,Graduate School of Science,Kyoto University
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Sugita Ayumu
Department Of Applied Physics Osaka City University
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Okamoto Ryoji
Department Of Physics Faculty Of Engineering Kyushu Institute Of Technology
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Yoshida Kenichi
Department Of Forensic Medicine Graduate School Of Medicine University Of Tokyo
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Matsuyanagi Kenichi
Department Of Physics Kyoto Univeristy
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MATSUO MASAYUKI
Graduate School of Science and Technology, Niigata University
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HINOHARA Nobuo
Department of Physics and Astronomy, University of North Carolina
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MATSUYANAGI Kenichi
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center
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YOSHIDA Kenichi
Department of Life Sciences, School of Agriculture, Meiji University
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Matsuyanagi Kenichi
Department Of Physics Kyoto University
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Marumori T
Department Of Physics Science University Of Tokyo
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OGASAWARA Hiromichi
Department of Physics, Graduate School of Science, Kyoto University
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FEDOTKIN Sergey
Institute for Nuclear Research
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Yoshida Kenichi
Department Of Legal Medicine Graduate School Of Medicine University Of Tokyo
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Kobayashi Masanori
Department Of Physics Graduate School Of Science Kyoto University
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Ogasawara Hiromichi
Department Of Physics Graduate School Of Science Kyoto University
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Kobayashi Masato
Department Of Bioengineering Tokyo Institute Of Technology
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SHIMIZU Yoshifumi
Department of Physics, Kyoto University
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KOBAYASHI Masato
Department of Electronics, Kyushy University
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MATSUO Masayuki
Yukawa Institute for Theoretical Physics, Kyoto University
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NAKATSUKASA Takashi
RI Beam Science Laboratory, RIKEN
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Nakatsukasa Takashi
Department Of Physics Kyoto University
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Nakatsukasa Takashi
Physics Department Tohoku University
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Magner A
Department Of Physics Graduate School Of Science Kyoto University:laboratoire De Spectrometrie Physi
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SAKATA Fumihiko
Institute for Nuclear Study, University of Tokyo
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Sugita Ayumu
Department Of Physics Graduate School Of Science Kyoto University
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Marumori Toshio
Department Of Physics Science University Of Tokyo
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Marumori Toshio
Department Of Physics Kyoto University
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Sakata Fumihiko
Institute For Nuclear Study The University Of Tokyo
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INAKURA Tsunenori
Department of Physics, Graduate School of Science, Kyoto University
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YAMAGAMI Masayuki
Department of Physics, Graduate School of Science, Kyoto University
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MIZUTORI Shoujirou
Yukawa Institute for Theoretical Physics, Kyoto University
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MAGNER Alexander
Research Center for Nuclear Physics, Osaka University
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SUZUKI Toru
Research Center for Nuclear Physics, Osaka University
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Fedotkin S
Institute For Nuclear Research:institute For Theoretical Physics University Of Regensburg
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Sakata F
Ibaraki Univ. Mito Jpn
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Inakura Tsunenori
Department Of Physics Graduate School Of Science Kyoto University
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Matsuzaki M
Department Of Physics Fukuoka University Of Education
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Matsuzaki Masayuki
Department Of Physics Fukuoha University Of Education
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Matsuo Masayuki
Yukawa Institute For Theoretical Physics Kyoto University
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Shimizu Yoshifumi
Department Of Physics Kyoto University
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Suzuki Toru
Research Center For Nuclear Physics Osaka University
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MAGNER Alexander
Institute for Nuclear Research : Institute for Theoretical Physics, University of Regensburg : Department of Physics, Graduate School of Science, Kyoto University
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MIZUTORI Shoujirou
Department of Human Science, Kansai Women's College
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Fedotkin Sergey
Institute for Nuclear Research:Institute for Theoretical Physics, University of Regensburg
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SATO Koichi
Department of Physics, Graduate School of Science, Kyoto University
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在田 謙一郎
名古屋工業大学
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在田 謙一郎
名古屋工業大学工学部
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岡本 良治
九工大工
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Fukui Takahiro
Department of Cardiology
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Matsuo M
Department Of Physics Kyoto University
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HlNOHARA Nobuo
Department of Physics, Graduate School of Science, Kyoto University
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FUKUl Takahiro
Department of Physics, Kyoto University
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Brack Matthias
Institute For Theoretical Physics University Of Regensburg
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Fukui T
Department Of Synthetic Chemistry And Biological Chemistry Graduate School Of Engineering Kyoto Univ
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YAMAGAMI MASAYUKI
Radioactive Isotope Physics Laboratory, RIKEN, Wako
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MIZUTORI SHOUJIROU
Kansai women's college
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YAMAGAMI MASAYUKI
RIKEN, Wako
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Aiba H
Osaka Univ. Ibaraki
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AIBA Hirokazu
Department of Physics, Kyoto University
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SUZUKI Toru
Institut fur Kernphysik, Kernforschungsanlage Julich
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Fukul Takahiro
Department Of Physics Kyoto University
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Sato Koichi
Department Of Cardio-renal Medicine And Hypertension Nagoya City University Graduate School Of Medic
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在田 謙一郎
名古屋工大 工
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Fedotkin Sergey
Institute For Nuclear Research : Institute For Theoretical Physics University Of Regensburg
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MAGNER Alexander
Institute for Nuclear Research
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MISU Toshiyuki
Cyclotron Radio-isotope Center, Tohoku University
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SCHACHNER Thomas
Institute for Theoretical Physics, University of Regensburg
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Yamagami Masayuki
Radioactive Isotope Physics Laboratory Riken
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Matsuo Masayuki
Department Of Physics Kyoto University
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Misu Toshiyuki
Cyclotron Radio-isotope Center Tohoku University
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Arita Kenichiro
Department Of Physics Nagoya Institute Of Technology
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Matsuyanagi Kenichi
Department Of Physics Kyushu University
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Magner Alexander
Institute For Nuclear Research : Institute For Theoretical Physics University Of Regensburg : Depart
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Matsumoto Masayuki
Department Of Cardiology Kyushu Kousei-nenkin Hospital
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Sato Koichi
Department Of Physics Graduate School Of Science Kyoto University:theoretical Nuclear Physics Labora
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Sato Koichi
Department Of Artificial Organs National Cardiovascular Center Research Institute
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Schachner Thomas
Institute For Theoretical Physics University Of Regensburg
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SHUMIZU Yoshifumi
Department of Physics, Kyoto University
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MATSUO Masayuki
RI Beam Science Laboratory RIKEN
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SHIMIZU Yoshifumi.
Department of Physics, Kyushu University
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BRACK Matthias
Institute for Theoretical Physics, University of Regensburg
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Yamagami Masayuki
Department of Chemistry Radiation Center of Osaka Prefecture
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Matsuyanagi Ken-ichi
Department of Physics, Kyoto University
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MATSUYANAGI Kenichi
Theoretical Nuclear Physics Laboratory, RIKEN Nishina Center:Yukawa Institute for Theoretical Physics, Kyoto University
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MARUMORI Toshio
Department of Physics, Kyushu University
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MAGNER Alexander
Research Center for Nuclear Physics, Osaka University:Institute for Nuclear Research:Institute for Theoretical Physics, University of Regensburg
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ARITA Ken-ichiro
Department of Physics,Nagoya Institute of Technology
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OKAMOTO Ryoji
Department of Physics,Kyushu University
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KURIYAMA Atsushi
Department of Physics,Kyushu University
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MATSUYANAGI Kenichi
Department of Physics, Kyushu University
著作論文
- A Model Analysis of Triaxial Deformation Dynamics in Oblate-Prolate Shape Coexistence Phenomena(Nuclear Physics)
- 有限量子系のシェル構造と古典周期軌道
- Microscopic Derivation of Collective Hamiltonian by Means of the Adiabatic Self-Consistent Collective Coordinate Method : Shape Mixing in Low-Lying States of ^Se and ^Kr(Nuclear Physics)
- Microscopic Description of Shape Coexistence Phenomena around ^Se and ^Kr(International Workshop on Nuclear Structure-New Pictures in the Extended Isospin Space(NS07)-)
- Gauge-Invariant Formulation of the Adiabatic Self-Consistent Collective Coordinate Method(Nuclear Physics)
- Effects of Time-Odd Components in Mean Field on Large Amplitude Collective Dynamics (Nuclear Physics)
- Collective Paths Connecting the Oblate and Prolate Shapes in ^Se and ^Kr Suggested by the Adiabatic Self-Consistent Collective Coordinate Method(Nuclear Physics)
- Collective Path Connecting the Oblate and Prolate Local Minima in ^Se
- Application of the Adiabatic Self-Consistent Collective Coordinate Method to a Solvable Model of Prolate-Oblate Shape Coexistence(Nuclear Physics)
- Diabatic Mean-Field Description of Rotational Bands in Terms of the Selfconsistent Collective Coordinate Method
- Adiabatic Selfconsistent Collective Coordinate Method for Large Amplitude Collective Motion in Nuclei with Pairing Correlations
- Semiclassical Origin of Superdeformed Shell Structure in the Spheroidal Cavity Model : Nuclear Physics
- Periodic-Orbit Bifurcation and Shell Structure in Reflection-Asymmetric Deformed Cavity : Nuclear Physics
- Soft Octupole Vibrations with K=0 and K≠0 Built on Superdeformed Rotational Bands and Static Pairing Correlations : Nuclear Physics
- Octupole Vibrations with K=1 and 2 in Superconducting, Superdeformed Nuclei : Nuclear Physics
- Diabatic Approach to Shape Coexistence Phenomena in Semi-Magic Nuclei. I : Illustration of Basic Ideas : Nuclear Physics
- 22aSD-2 不安定核の集団現象に対する微視的アプローチ(22aSD 実験核物理領域,理論核物理領域合同招待講演,実験核物理領域)
- 原子核における変形共存現象と大振幅集団運動(有限量子多体系の励起構造と相関効果-原子核・量子ドット・ボース凝縮・クラスターを中心として-,研究会報告)
- 原子核における変形共存現象と大振幅集団運動(「有限量子多体系の励起構造と相関効果」-原子核・量子ドット・ボース凝縮・クラスターを中心として-,研究会報告)
- Rotational Frequency Dependence of Octupole Vibrations on Superdeformed States in ^Ca(Nuclear Physics)
- Triaxiality Dependence of Octupole Excitations on Superdeformed States in ^Ti(Nuclear Physics)
- Soft K^π=0^+ modes unique to deformed neutron-rich nuclei(International Workshop on Nuclear Structure-New Pictures in the Extended Isospin Space(NS07)-)
- Rotating RPA Calculation for Collective Vibrational Modes built on Superdeformed Bands in the ^Ca Region(International Workshop on Nuclear Structure-New Pictures in the Extended Isospin Space(NS07)-)
- Comparative Study of Octupole Excitations on Superdeformed States in ^S, ^S, ^Ca and ^S(Nuclear Physics)
- Cranked Skyrme-Hartree-Fock Calculations for Superdeformed and Hyperdeformed Bands in N = Z Nuclei, ^32S, ^36Ar, ^40Ca, and in Neutron Rich Nuclei, ^14Be, ^26Ne, ^46S
- Cranked Skyrme-Hartree-Fock Calculations for Superdeformed and Hyperdeformed Bands in N=Z Nuclei, ^S, ^Ar, ^Ca, and in Neutron Rich Nuclei, ^Be, ^Ne, ^S
- Symmetry Breaking and Bifurcations in the Periodic Orbit Theory.II : Spheroidal Cavity
- Symmetry Breaking and Bifurcations in the Periodic Orbit Theory. II : Spheroidal Cavity
- Analysis of Collective- Noncollective Couplings in a Degenerate Many j-Shell Model : Nuclear Physics
- Residual Interactions between Aligned Quasiparticles and Pairing Deformation Changes in ^Yb and ^Er
- Dynamical Interplay of Pairing and Quadrupole Modes in Transitional Nuclei.III
- Dynamical Interplay of Pairing and Quadrupole Modes in Transitional Nuclei. II
- Dynamical Interplay of Pairing and Quadrupole Modes in Transitional Nuclei. I
- Property of Many-Phonon Norm Matrix
- Chapter 7. Coupling between Collective and Intrinsic Modes of Excitation : Part IV. A Next Subject
- Chapter 5. Microscopic Structure of Breaking and Persistency of "Phonon-plus-Odd-Quasi-Particle Picture" : Part III. Analysis of Low-Lying States in Spherical Odd-Mass Nuclei
- Chapter 4. Persistency of AC State-Like Structure in Collective Excitations : Odd-Mass Mo, Ru, I, Cs and La Isotopes : Part III. Analysis of Low-Lying States in Spherical Odd-Mass Nuclei
- Chapter 3. Structure of the Anomalous Coupling States with Spin I=(j-1) : Part III. Analysis of Low-Lying States in Spherical Odd-Mass Nuclei
- Chapter 2. Theory of Intrinsic Modes of Excitation in Odd-Mass Nuclei : Part II. General Formulation of Theory
- Chapter 1. Intrinsic and Collective Degrees of Freedom in Quasi-Spin Space : Part II. General Formulation of Theory
- Part I. Introduction
- Microscopic Structure of a New Type of Collective Excitation in Odd-Mass Mo, Ru, I, Cs and La Isotopes
- Theory of Collective Excitations in Spherical Odd-Mass Nuclei. IV : Formulation in the General Many-j-Shell Model
- Theory of Collective Excitations in Spherical Odd-Mass Nuclei. II : Structure of the Anomalous Coupling States with Spin I = (j-1)
- Theory of Collective Excitations in Spherical Odd-Mass Nuclei. I : Basic Ideas and Concept of Dressed Three-Quasi-Particle Modes
- Effects of Octupole Vibrations on Quasiparticle Modes of Excitation in Superdeformed ^Hg : Nuclear Physics
- Octupole Vibrations in the Harmonic-Oscillator-Potential Model with Axis Ratio Two to One : Nuclear Physics
- Interplay of Gamma-Vibrations and Aligned-Quasiparticles at High-Spin Yrast Region : Nuclear Physics
- An Extension of the Rotating Shell Model and Its Application to ^Er
- Microscopic Description of Anharmonic Gamma-Vibrations by Means of the Selfconsistent-Collective-Coordinate Method. III
- Symmetry Breaking and Bifurcations in the Periodic Orbit Theory. I : Elliptic Billiard
- Octupole Vibrations Built on Superdeformed Rotational Bands : Progress Letters
- Quasiparticle-Vibration Couplings in Rotating Triaxial Odd-A Nuclei : Nuclear Physics
- Signature Dependence of M1 and E2 Transitions in Rotating Triaxial Odd-A Nuclei
- Semiclassical Analysis of the Supershell Effect in Reflection-Asymmetric Superdeformed Oscillator : Nuclear Physics
- Octupole Instability of the Closed-Shell Configurations in the Superdeformed Oscillator Potential : Nuclear Physics
- Microscopic Description of Anharmonic Gamma-Vibrations by Means of the Selfconsistent-Collective-Coordinate Method. I : Nuclear Physics
- Microscopic Description of Anharmonic Gamma-Vibrations by Means of the Selfconsistent-Collective-Coordinate Method. II : Nuclear Physics
- Applicability of the Canonical Quantization Procedure for the Collective Hamiltonian Derived by the SelfConsistent-Collective-Coordinate Method : Nuclear Physics
- Chapter 6. Comparison between Results with the P+QQ Force and with More Complex Residual Force : Part III. Analysis of Low-Lying States in Spherical Odd-Mass Nuclei
- Incipient Triaxial Deformations of the Rotation-Aligned Bands : Equilibrium Shapes Determined by the Isotropic Velocity Distribution Condition : Nuclear Physics
- Interplay of Pairing and Intrinsic Modes of Excitation in Nuclei. I : Transcription of Nucleon System into Ideal Boson-Quasi-Particle Space
- Diabatic Quasiparticle Representation for Rotating Shell Model
- Attenuation Factors for B(E2) in the Microscopic Description of Multiphonon States : A Simple Model Analysis
- Structure of Anomalous Coupling (j-1) States
- Monopole and Quadrupole Giant Resonances in Rotating Triaxially Deformed Nuclei. II : A Microscopic Description of the Isoscalar and Isovector Modes : Nuclear Physics
- High-Spin Anomaly of Gamma Band and Rotation-Alignment Effects in ^Er
- Rotational Frequency Dependence of Gamma Vibration and Pairing Potential in ^Er
- Monopole and Quadrupole Giant Resonances in Rotating Triaxially Deformmed Nuclei : Nuclear Physics
- Adiabatic Selfconsistent Collective Coordinate Method for Large Amplitude Collective Motion in Nuclei with Pairing Correlations
- Microscopic Derivation of Collective Hamiltonian by Means of the Adiabatic Self-Consistent Collective Coordinate Method : Shape Mixing in Low-Lying States of ^Se and ^Kr
- Gauge-Invariant Formulation of the Adiabatic Self-Consistent Collective Coordinate Method
- Effects of Time-Odd Components in Mean Field on Large Amplitude Collective Dynamics
- Collective Path Connecting the Oblate and Prolate Local Minima in ^Se
- Application of the Adiabatic Self-Consistent Collective Coordinate Method to a Solvable Model of Prolate-Oblate Shape Coexistence
- Diabatic Mean-Field Description of Rotational Bands in Terms of the Selfconsistent Collective Coordinate Method
- Periodic-Orbit Bifurcation and Shell Structure in Reflection-Asymmetric Deformed Cavity : Nuclear Physics
- Semiclassical Origin of Superdeformed Shell Structure in the Spheroidal Cavity Model : Nuclear Physics
- Collective Paths Connecting the Oblate and Prolate Shapes in ^Se and ^Kr Suggested by the Adiabatic Self-Consistent Collective Coordinate Method(Nuclear Physics)
- Comparative Study of Octupole Excitations on Superdeformed States in ^S, ^S, ^Ca and ^S(Nuclear Physics)