Quantum Theory of Collective Motion : Quantized Self-Consistent Collective-Coordinate Method for the Large-Amplitude Nuclear Collective Motion
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概要
- 論文の詳細を見る
This is the third in a series of papers which intends to develop a new microscopic theory capable by itself to determine the "maximaldecoupled" collective subspace in the many-particle Hilbert space as well as the collective Hamiltonian specifying the subspace. The fundamental principle to formulate the theory is called the invariance principle of the Schrodinger equation. The main purpose of this paper is to show that, when we positively utilize the invariance principle, we can directly obtain a quantum theory of collective motion going beyond the random phase approximation.
- 理論物理学刊行会の論文
- 1981-11-25
著者
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HASHIMOTO Yukio
Institute of Physics, University of Tsukuba
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SAKATA Fumihiko
Institute for Nuclear Study, University of Tokyo
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MARUMORI Toshio
Institute of Physics, University of Tsukuba
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Marumori T
Department Of Physics Science University Of Tokyo
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Marumori Toshio
Institute For Nuclear Study University Of Tokyo
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Sakata Fumihiko
Institute For Nuclear Study The University Of Tokyo
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MASKAWA Toshihide
Institute for Nuclear Study, University of Tokyo
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Hashimoto Yukio
Institute Of Physics University Of Tsukuba
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UNE Tsutomu
Institute of Physics, University of Tsukuba
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Une T
Univ. Tsukuba Ibaraki Jpn
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Une Tsutomu
Institute Of Physics University Of Tsukuba
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Sakata F
Ibaraki Univ. Mito Jpn
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UNE Tsutom
Institute of Physics, University of Tsukuba
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MASKAWA Toshihide
Research Institute for Fundamental Physics Kyoto University
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UNE Tsutomu
Institute of Physics, University of Tsukaba
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HASHIMOTO Yukio
Institute for Nuclear Study, University of Tokyo
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HASHIMOTO Yukio
Institute of Physics, University of Tsukaba
関連論文
- 実空間におけるRPA方程式の解法(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)
- 実空間における RPA 方程式の解法(「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)
- Solving the RPA Eigenvalue Equation in Real-Space(Nuclear Physics)
- Solving the RPA Eigenvalue Equation in Real-Space
- Breaking of Separability Condition for Dynamical Collective Subspace : Onset of Quantum Chaos in Large-Amplitude Collective Motion : Nuclear Phusics
- Concept of a Collective Subspace Associated with the Invariance Principle of the Schrodinger Equation:A Microscopic Theory of the Large Amplitude Collective Motion of Soft Nuclei
- On Singularities and Asymptotic Behaviors in Kaluza-Klein Cosmology : Particles and Fields
- Preface
- 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
- Equations of Motion for the System of Interest under Time-Dependent Environment(Nuclear Physics)
- The Influence of the Pairing Degrees of Freedom on the Collective Excited States : Schematic Analysis
- Projection Operator Method for Collective Tunneling Transitions
- A Possible Microscopic Description of Nuclear Collective Rotation in Band-Crossing Region:Occurrence Mechanism of s-Band
- Work with Maskawa on Microscopic Theory of Nuclear Collective Motion(Commemorating the Nobel Prize Awarded to M. Kobayashi and T. Maskawa)
- Chapter I Formation of the Viewpoint, Alpha-Like Four-Body Correlations and Molecular Aspects in Nuclei
- Bifurcation Structure of Eigenstates and Periodic Trajectories in TDHF Phase Space : Weak Nonlinearity Case in SU(3) Model : Nuclear Physics
- A Numerical Study on the Structure Change of Collective Motions
- New Algorithm for Hartree-Fock Variational Equation : Nuclear Physics
- Quantum Nonlinear Resonance : Nuclear Physics
- Microscopic Description of Nuclear Collective Rotation by Means of the Self-Consistent Collective Coordinate Method : Occurrence Mechanism of Collective Rotation : Nuclear Physics
- Extraction of Dynamical Collective Subspace for Large-Amplitude Collective Motion : Application to Simple Solvable Model : Nuclear Physics
- Optimum Collective Submanifold in Resonant Cases by the Self-Consistent Collective-Coordinate Method for Large-Amplitude Collective Motion
- Collective, Dissipative and Stochastic Motions in the TDHF Theory : Nuclear Physics
- Concept of Dynamical Collective Submanifold for Large-Amplitude Collective Motion in the TDHF Theory : Nuclear Physics
- Intrinsic Excitation Modes Compatible with Large-Amplitude Collective Motion in the TDHF Theory : Nuclear Physics
- Applicability of the Concept of "Optimal" Collective Submanifold Determined by the Self-Consistent Collective-Coordinate Method : Long-Time Behavior of Trajectories on "Optimal" Collective Submanifold : Nuclear Physics
- Geometry of the Self-Consistent Collective-Coordinate Method for the Large-Amplitude Collective Motion : Stability Condition of Maximally-Decoupled Collective Submanifold
- Maximally-Decoupled Collective Submanifold in a Simple Solvable Model
- An Attempt toward Quantum Theory of "Maximally-Decoupled"Collective Motion
- Quantum Theory of Collective Motion : Quantized Self-Consistent Collective-Coordinate Method for the Large-Amplitude Nuclear Collective Motion
- Self-Consistent Collective-Coordinate Method for the Large-Amplitude Nuclear Collective Motion
- The Problem of P^+=0 Mode in the Null-Plane Field Theory and Dirac's Method of Quantization
- The Theory of the Structure of Elementary Particles
- Local Gaussian Approximation in the Generator Coordinate Method
- A Step toward Large-Amplitude Description of the Ground Band around Band Crossing
- On the Extended Siegert Theorem
- Quantization of the Adiabatic TDHF Theory of Large Amplitude Collective Motion
- Collective Hamiltonian in the Generator Coordinate Method with Local Gaussian Approximation
- Finite-Range DWBA Analysis of Anomalous Analyzing Powers in (p,α) Reactions
- Nonlinear Dynamics of Nuclear Collective Motion
- Dynamical Properties of the GCM Rotational Hamiltonian : Dynamics of the Transition from Collective to Noncollective Rotation : Nuclear Physics
- Study of Tilted Rotation Based on the Method of Variation after Projection
- A Microscopic Theory of the So-Called "Two-Phonon" States in Even-Even Nuclei. II : Formulation
- Chapter 2 Outline of the Mode-Mode Coupling Theory
- Chapter 1 Present Status of the Microscopic Study of Low-Lying Collective States in Spherical and Transitional Nuclei
- A New Method for Microscopic Description of the So-Called "Many-Phonon" States in Spherical Even-Even Nuclei. I
- Structure of the Anomalous 0^ Excited States in Spherical Even-Even Nuclei with N or Z≈ 40
- In What Sense Does the Phonon Picture Persist in Spherical Even-Even Nuclei?
- Chapter VI Many-Body Theoretical Description of Alpha-Like Four-Body Correlations
- Chapter 5 Dynamical Interplay between Pairing and Quadrupole Correlations in Odd-Mass Nuclei
- Chapter 4 Dynamical Interplay between Pairing and Quadrupole Correlations : Anharmonicity in the So-Called Two-Phonon Triplet States in Medium-Heavy Nuclei
- Chapter 3 A New Microscopic Method for Describing the Elementary Modes of Excitation in the Intrinsic Subspace : Dressed n-Quasiparticle Modes and Multi-Phonon Excitation
- Correlation Analysis of Quantum Fluctuations and Repulsion Effects of Classical Dynamics in SU(3) model(Nuclear Physics)
- Dissipation Mechanism of the Large-Amplitude Collective Motion : Dynamical Evolution of a Collective Bundle of Trajectories in the TDHF Phase Space for a Simple Soluble Model : Nuclear Physics
- On the Foundation of the Unified Nuclear Model, I
- On the Universal Fermi Interaction
- On the Conservation of Heavy Particles
- Nonlinear σ Models on Symmetric Spaces and Large N Limit
- Structure of the Gauge Transformation Group in the Square Integrable Space and Gribov's Ambiguity in the Coulomb Gauge
- Non-Linear Realization in Supersymmetric Theories : Particles and Fields
- Spontaneous Breaking of Chiral Symmetry in a Vector-Gluon Model
- Non-Linear Realization in Supersymmetric Theories. II : Particles and Fields
- New Bound for Single and Double Diffraction Cross Sections in Identical Particle Collisions
- Bag Theory with the Dirichlet Boundary Conditions and Spontaneous Symmetry Breakdown
- Singular Lagrangian an the Dirac-Feddeev Method : Existence Theorems of constraints in 'Standard Form'
- Spontaneous Breaking of Chiral Symmetry in a Vector-Gluon Model. II
- How Dense Are the Coulomb Gauge Fixing Degeneracies? : Geometrical Formulation of the Coulomb Gauge
- On the Nuclear Saturation
- Quantum Theory of Dynamical Collective Subspace for Large-Amplitude Collective Motion : Nuclear Physics
- A Microscopic Theory of Large Amplitude Nuclear Collective Motion
- On the Relation between Hill-Wheeler's and Bohr-Mottelson's Descriptions of the Nuclear Collective Model
- On the "Optical Method" for the Scattering of High Energy Particles by Complex Nuclei
- Present Status of the Microscopic Study of Low-Lying Collective States in Spherical and Transitional Nuclei (Microscopic Study of Low-Lying Collective States in Spherical and Transitional Nuclei--Dynamical Interplay between Pairing and Quadrupole Modes)
- Bifurcation Structure of Eigenstates and Periodic Trajectories in TDHF Phase Space : Weak Nonlinearity Case in SU(3) Model : Nuclear Physics
- A Microscopic Theory of Large Amplitude Nuclear Collective Motion