Properties of Nuclear Matter for the Proposed NN One-Boson-Exchange Potential with Full Nonstatic Effects
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概要
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The properties of nuclear matter have been calculated to first order of the reaction matrix G. The Brueckner-Bethe-Goldstone equation for G has been solved in momentum space, with the single-particle potential energy being taken to be zero for particle states above the Fermi surface. The two-body interaction assumed is the proposed one-boson-exchange type potential represented in momentum space. It is found that the binding energy is -12.3 MeV/particle at a saturation density corresponding to the Fermi momentum of 1.57 fm^<^1>, the compressibility is 148 MeV and the defect parameter is 0.133 at the saturation density. The saturation comes about essentially from tensor force. Influence of the experimental uncertainty in the ^3S_1-^3D_1 mixing parameter on nuclear matter is discussed. The results are compared with corresponding ones of other potentials.
- 理論物理学刊行会の論文
- 1974-10-25
著者
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Hoshizaki Norio
Department Of Nuclear Engineering Faculty Of Engineering Kyoto University
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KADOTA Tsuyoshi
Department of Radiology, The Center for Adult Diseases
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KASAHARA Teruhisa
Hokkaido University Computing Center, Hokkaido University
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Kadota Tsuyoshi
Department Of Nuclear Engineering Kyoto University
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Kasahara Teruhisa
Hokkaido University Computing Center
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Hoshizaki Norio
Department Of Neuclear Engineering Faculty Of Engineering Kyoto University
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HOSHIZAKI Norio
Department of Nuclear Engineering,Kyoto University
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Kasahara Tyuyo
Computing Center, Faculty of Science, Hokkaido University
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