A Microscopic Description of Nuclear Rotational Motion. I
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概要
- 論文の詳細を見る
A new microscopic description of the nuclear rotational problem is formulated by introducing a tensor operator R^<2M> which generates rotational states. "The Tomonaga-Lipkin condition" for the separation of rotational motion is adopted as our fundamental equation of motion which should be satisfied by the operator R^<2M>. Suitable intrinsic states are defined in a consistent way with this equation of motion. The structure of wave functions is similar to that of the Peierls-Yoccoz method. However our method gives a right answer for the center-of-mass problem because intrinsic states are suitably chosen. Our basic formalism is applied to single-j shell system with a quadruple force. The moment of inertia is determined so that the fundamental equation for the operator R^<2M> is satisfied. The result agrees with that obtained by applying the Hartree approximation and the cranking model to this system.
- 理論物理学刊行会の論文
- 1978-11-25
著者
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Shono Yoshiyuki
Division Of Mathematical Physics Faculty Of Engineering Fukui University
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SHONO Yoshiyuki
Division of Mathematical Physics, Faculty of Engineering Fukui University
関連論文
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- A Microscopic Description of Nuclear Rotational Motion. I
- Microscopic Cluster Model for the ^9_∧Be Hypernucleus
- A Microscopic Description of Nuclear Rotational Motions. III : Equation of Motion in the Intrinsic Space
- A Microscopic Description of Nuclear Rotational Motion. II : Rotation and HF Approximation