Binding Energy of Nuclear Matter by the Hole Line Expansion Method. I
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概要
- 論文の詳細を見る
The theory of nuclear matter is modified in such a way that the concept of the one-body potential is given up for the off-energy shell and kept only for the on-energy shell. In this method no longer occur such complications as many-particle excitations which couple one by one through the off-energy shell potential and we treat all higher order terms with a given number of hole lines as a whole. Following this method the two-body and three-body contributions to the binding energy are calculated for the hard core and soft core potentials. The two-body contributions are about 10 MeV for the soft core and 5 to 7 MeV for the hard core potentials. The three-body contribution is found to be sensitive to the behavior of the two-body correlation function in the outer healing region. The three-body contributions are repulsive and about 0.5MeV at r_0=1.1 fm for the soft core and 0.8MeV at r_0=1.6 fm for the H-J potential.
- 理論物理学刊行会の論文
- 1968-08-25
著者
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AKAISHI Yoshinori
Department of Physics, Hokkaido University
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NAGATA Sinobu
Department of Physics, Kyoto University
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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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Akaishi Yoshinori
Department Of Physics Hokkaido University
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Nagata Sinobu
Department Of Applied Physics Faculty Of Engineering Miyazaki University
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Bando Hiroharu
Department Of Physics Kyoto University
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BANDO Hiroharu
Department of Physics, Kyoto University
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AKAISHI Yoshinori
Department of Physics, Kyoto University
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