The role of isospin symmetry in collective nuclear structure

D. D. Warner; M. A. Bentley; P. Van Isacker

doi:10.1038/nphys291

The role of isospin symmetry in collective nuclear structure

D. D. Warner, M. A. Bentley, P. Van Isacker

Physics

Research output: Contribution to journal › Literature review › peer-review

Abstract

The nucleus is a unique laboratory in physics - a quantum many-body system comprising two types of fermion, the neutron and proton, differing in charge but otherwise essentially identical in their behaviour. The fact that the strong interaction between these fermions is largely independent of charge results in striking symmetries in nuclei. This neutron - proton exchange invariance is encompassed in the elegant concept and formalism of Wigner's isotopic spin - or isospin. The impact of isospin symmetry is maximal near the N=Z line where nuclei have equal numbers of neutrons and protons, and studies involving isospin effects have undergone a resurgence in recent years as such nuclei become more readily accessible. In this review we discuss three isospin- related phenomena: the elegant isospin symmetry of excited analogue states in nuclei, the origin of the extra binding for nuclei with equal numbers of neutrons and protons and the exotic phenomenon of neutron - proton pairing. These three topics, all of considerable current interest, demonstrate the power, simplicity and modern relevance of the isospin concept.

Original language	English
Pages (from-to)	311-318
Number of pages	8
Journal	Nature Physics
Volume	2
Issue number	5
DOIs	https://doi.org/10.1038/nphys291
Publication status	Published - May 2006

Keywords

HIGH-SPIN STATES
FULL PF SHELL
MIRROR NUCLEI
PAIRING MODELS
SPECTROSCOPY
ENERGIES
CR-49
ORIGIN
FORCES
MN-50

Access to Document

10.1038/nphys291

Cite this

@article{9f79bf8aac5e454981da0730f3619daf,

title = "The role of isospin symmetry in collective nuclear structure",

abstract = "The nucleus is a unique laboratory in physics - a quantum many-body system comprising two types of fermion, the neutron and proton, differing in charge but otherwise essentially identical in their behaviour. The fact that the strong interaction between these fermions is largely independent of charge results in striking symmetries in nuclei. This neutron - proton exchange invariance is encompassed in the elegant concept and formalism of Wigner's isotopic spin - or isospin. The impact of isospin symmetry is maximal near the N=Z line where nuclei have equal numbers of neutrons and protons, and studies involving isospin effects have undergone a resurgence in recent years as such nuclei become more readily accessible. In this review we discuss three isospin- related phenomena: the elegant isospin symmetry of excited analogue states in nuclei, the origin of the extra binding for nuclei with equal numbers of neutrons and protons and the exotic phenomenon of neutron - proton pairing. These three topics, all of considerable current interest, demonstrate the power, simplicity and modern relevance of the isospin concept.",

keywords = "HIGH-SPIN STATES, FULL PF SHELL, MIRROR NUCLEI, PAIRING MODELS, SPECTROSCOPY, ENERGIES, CR-49, ORIGIN, FORCES, MN-50",

author = "Warner, {D. D.} and Bentley, {M. A.} and {Van Isacker}, P.",

year = "2006",

month = may,

doi = "10.1038/nphys291",

language = "English",

volume = "2",

pages = "311--318",

journal = "Nature Physics",

issn = "1745-2473",

publisher = "Nature Publishing Group",

number = "5",

}

TY - JOUR

T1 - The role of isospin symmetry in collective nuclear structure

AU - Warner, D. D.

AU - Bentley, M. A.

AU - Van Isacker, P.

PY - 2006/5

Y1 - 2006/5

N2 - The nucleus is a unique laboratory in physics - a quantum many-body system comprising two types of fermion, the neutron and proton, differing in charge but otherwise essentially identical in their behaviour. The fact that the strong interaction between these fermions is largely independent of charge results in striking symmetries in nuclei. This neutron - proton exchange invariance is encompassed in the elegant concept and formalism of Wigner's isotopic spin - or isospin. The impact of isospin symmetry is maximal near the N=Z line where nuclei have equal numbers of neutrons and protons, and studies involving isospin effects have undergone a resurgence in recent years as such nuclei become more readily accessible. In this review we discuss three isospin- related phenomena: the elegant isospin symmetry of excited analogue states in nuclei, the origin of the extra binding for nuclei with equal numbers of neutrons and protons and the exotic phenomenon of neutron - proton pairing. These three topics, all of considerable current interest, demonstrate the power, simplicity and modern relevance of the isospin concept.

AB - The nucleus is a unique laboratory in physics - a quantum many-body system comprising two types of fermion, the neutron and proton, differing in charge but otherwise essentially identical in their behaviour. The fact that the strong interaction between these fermions is largely independent of charge results in striking symmetries in nuclei. This neutron - proton exchange invariance is encompassed in the elegant concept and formalism of Wigner's isotopic spin - or isospin. The impact of isospin symmetry is maximal near the N=Z line where nuclei have equal numbers of neutrons and protons, and studies involving isospin effects have undergone a resurgence in recent years as such nuclei become more readily accessible. In this review we discuss three isospin- related phenomena: the elegant isospin symmetry of excited analogue states in nuclei, the origin of the extra binding for nuclei with equal numbers of neutrons and protons and the exotic phenomenon of neutron - proton pairing. These three topics, all of considerable current interest, demonstrate the power, simplicity and modern relevance of the isospin concept.

KW - HIGH-SPIN STATES

KW - FULL PF SHELL

KW - MIRROR NUCLEI

KW - PAIRING MODELS

KW - SPECTROSCOPY

KW - ENERGIES

KW - CR-49

KW - ORIGIN

KW - FORCES

KW - MN-50

U2 - 10.1038/nphys291

DO - 10.1038/nphys291

M3 - Literature review

SN - 1745-2473

VL - 2

SP - 311

EP - 318

JO - Nature Physics

JF - Nature Physics

IS - 5

ER -