Amazon cover image
Image from Amazon.com

Nuclear physics with stable and radioactive ion beams = Fisica nucleare con fasci di ioni stabili e radioattivi / edited by F. Gramegna, P. Van Duppen and A. Vitturi, directors of the course and S. Pirone.

By: Contributor(s): Material type: TextTextSeries: International School of Physics "Enrico Fermi." Proceedings of the International School of Physics "Enrico Fermi" ; Course 201.Publisher: Amsterdam : IOS Press : IOS Press, 2019Description: 1 online resourceContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781614999577
  • 1614999570
Other title:
  • Fisica nucleare con fasci di ioni stabili e radioattivi
Subject(s): Genre/Form: DDC classification:
  • 539.7 23
LOC classification:
  • QC770
Online resources:
Contents:
Intro; Title Page; Contents; Preface; Course group shot; Recent developments in shell model studies of atomic nuclei; 1. Introduction; 2. Basic points of the shell model; 3. Computational aspect-Monte Carlo Shell Model; 4. Hamiltonians; 5. Emerging concepts on many-body dynamics; 6. Shell evolution and monopole interaction; 6.1. Monopole interaction; 6.2. Effect of monopole interaction; 7. Shell evolution due to nuclear forces; 7.1. Type-I shell evolution; 7.2. Shell evolution due to tensor force; 8. Nuclear shape; 8.1. Nuclear shapes and quantum phase transition
8.2. Quantum phase transition in Zr isotopes8.3. Quantum self-organization; 9. Summary and perspectives; Algebraic models of quantum many-body systems: The algebraic cluster model; 1. Introduction; 2. Cluster structure of light nuclei; 3. The algebraic cluster model; 3.1. Classification of states; 3.1.1. Dumbbell configuration, k = 2. Z2 symmetry; 3.1.2. Equilateral-triangle configuration, k = 3. D3h symmetry; 3.1.3. Tetrahedral configuration, k = 4. Td symmetry; 3.2. Energy formulas; 3.2.1. Dumbbell configuration. Z2 symmetry; 3.2.2. Equilateral-triangle configuration. D3h symmetry
3.2.3. Tetrahedral configuration. Td symmetry3.3. Form factors and transition probabilities; 3.3.1. Dumbbell configuration. Z2 symmetry; 3.3.2. Equilateral-triangle configuration. D3h symmetry; 3.3.3. Tetrahedral configuration. Td symmetry; 3.4. Cluster densities; 3.4.1. Dumbbell configuration. Z2 symmetry; 3.4.2. Equilateral-triangle configuration. D3h symmetry; 3.4.3. Tetrahedral configuration. Td symmetry; 3.5. Moments of inertia and radii; 3.5.1. Dumbbell configuration. Z2 symmetry; 3.5.2. Equilateral-triangle configuration, k = 3. D3h symmetry
3.5.3. Tetrahedral configuration, k = 4. Td symmetry4. Evidence for cluster structures; 4.1. Energies; 4.1.1. Dumbbell configuration. Z2 symmetry; 4.1.2. Equilateral-triangle configuration. D3h symmetry; 4.1.3. Tetrahedral configuration. Td symmetry; 4.2. Electromagnetic transition rates; 4.2.1. Dumbbell configuration. Z2 symmetry; 4.2.2. Equilateral-triangle configuration. D3h symmetry; 4.2.3. Tetrahedral configuration. Td symmetry; 4.3. Form factors; 4.3.1. Dumbbell configuration. Z2 symmetry; 4.3.2. Equilateral-triangle configuration. D3h symmetry
4.3.3. Tetrahedral configuration. Td symmetry5. Breaking of the cluster structure. Non-cluster states; 6. Softness and higher-order corrections; 6.1. Dumbbell configuration. Z symmetry; 6.2. Equilateral-triangle configuration. D3h symmetry; 6.3. Tetrahedral configuration. Td symmetry; 7. Other geometric configurations; 8. Conclusions; Clustering in light neutron-rich nuclei; 1. Introduction; 2. Antisymmetrized molecular dynamics; 2.1. AMD wave function; 2.2. Cluster correlation; 3. Clustering in neutron-rich Be; 4. Clustering in 12C and neighboring nuclei; 4.1. Cluster structures of 12C
Holdings
Item type Current library Collection Call number Status Date due Barcode Item holds
eBook eBook e-Library EBSCO Science Available
Total holds: 0

Intro; Title Page; Contents; Preface; Course group shot; Recent developments in shell model studies of atomic nuclei; 1. Introduction; 2. Basic points of the shell model; 3. Computational aspect-Monte Carlo Shell Model; 4. Hamiltonians; 5. Emerging concepts on many-body dynamics; 6. Shell evolution and monopole interaction; 6.1. Monopole interaction; 6.2. Effect of monopole interaction; 7. Shell evolution due to nuclear forces; 7.1. Type-I shell evolution; 7.2. Shell evolution due to tensor force; 8. Nuclear shape; 8.1. Nuclear shapes and quantum phase transition

8.2. Quantum phase transition in Zr isotopes8.3. Quantum self-organization; 9. Summary and perspectives; Algebraic models of quantum many-body systems: The algebraic cluster model; 1. Introduction; 2. Cluster structure of light nuclei; 3. The algebraic cluster model; 3.1. Classification of states; 3.1.1. Dumbbell configuration, k = 2. Z2 symmetry; 3.1.2. Equilateral-triangle configuration, k = 3. D3h symmetry; 3.1.3. Tetrahedral configuration, k = 4. Td symmetry; 3.2. Energy formulas; 3.2.1. Dumbbell configuration. Z2 symmetry; 3.2.2. Equilateral-triangle configuration. D3h symmetry

3.2.3. Tetrahedral configuration. Td symmetry3.3. Form factors and transition probabilities; 3.3.1. Dumbbell configuration. Z2 symmetry; 3.3.2. Equilateral-triangle configuration. D3h symmetry; 3.3.3. Tetrahedral configuration. Td symmetry; 3.4. Cluster densities; 3.4.1. Dumbbell configuration. Z2 symmetry; 3.4.2. Equilateral-triangle configuration. D3h symmetry; 3.4.3. Tetrahedral configuration. Td symmetry; 3.5. Moments of inertia and radii; 3.5.1. Dumbbell configuration. Z2 symmetry; 3.5.2. Equilateral-triangle configuration, k = 3. D3h symmetry

3.5.3. Tetrahedral configuration, k = 4. Td symmetry4. Evidence for cluster structures; 4.1. Energies; 4.1.1. Dumbbell configuration. Z2 symmetry; 4.1.2. Equilateral-triangle configuration. D3h symmetry; 4.1.3. Tetrahedral configuration. Td symmetry; 4.2. Electromagnetic transition rates; 4.2.1. Dumbbell configuration. Z2 symmetry; 4.2.2. Equilateral-triangle configuration. D3h symmetry; 4.2.3. Tetrahedral configuration. Td symmetry; 4.3. Form factors; 4.3.1. Dumbbell configuration. Z2 symmetry; 4.3.2. Equilateral-triangle configuration. D3h symmetry

4.3.3. Tetrahedral configuration. Td symmetry5. Breaking of the cluster structure. Non-cluster states; 6. Softness and higher-order corrections; 6.1. Dumbbell configuration. Z symmetry; 6.2. Equilateral-triangle configuration. D3h symmetry; 6.3. Tetrahedral configuration. Td symmetry; 7. Other geometric configurations; 8. Conclusions; Clustering in light neutron-rich nuclei; 1. Introduction; 2. Antisymmetrized molecular dynamics; 2.1. AMD wave function; 2.2. Cluster correlation; 3. Clustering in neutron-rich Be; 4. Clustering in 12C and neighboring nuclei; 4.1. Cluster structures of 12C

Online resource; title from PDF title page (IOS Press, viewed August 5, 2019).

Added to collection customer.56279.3

Powered by Koha