Systematic study of the many- particle and many-hole states in and around the Island of Inversion - #N=Odd system - M. Kimura(Hokkaido)

Slides:



Advertisements
Similar presentations
Structure of  hypernuclei with the antisymmetrized molecular dynamics method Masahiro Isaka (RIKEN)
Advertisements

Spectroscopy at the Particle Threshold H. Lenske 1.
MINIBALL g-ray Spectroscopy far from Stability
Coulomb excitation with radioactive ion beams
2/June/2014 Advances in Radioactive Isotope Science (ARIS2014) the University of Tokyo S. Watanabe A K. Minomo, M. Shimada, S. Tagami, B M. Kimura, C M.
Isospin dependence and effective forces of the Relativistic Mean Field Model Georgios A. Lalazissis Aristotle University of Thessaloniki, Greece Georgios.
Testing shell model on nuclei
Deeply Bound Pionic States in Sn at RIBF N. Ikeno (Nara Women’s Univ. M1) J. Yamagata-Sekihara (IFIC, Valencia Univ.) H. Nagahiro (Nara Women’s Univ.)
Semi-magic seniority isomers and the effective interactions
Nuclear models. Models we will consider… Independent particle shell model Look at data that motivates the model Construct a model Make and test predictions.

NUCLEAR STRUCTURE PHENOMENOLOGICAL MODELS
1 TCP06 Parksville 8/5/06 Electron capture branching ratios for the nuclear matrix elements in double-beta decay using TITAN ◆ Nuclear matrix elements.
LIVING WITH TRANSFER AS AN EXPERIMENTAL SPECTROSCOPIST WILTON CATFORD TRENTO WORKSHOP 4-8 Nov 13 FROM NUCLEAR STRUCTURE TO PARTICLE-TRANSFER REACTIONS.
Structure of Be hyper-isotopes Masahiro ISAKA (RIKEN) Collaborators: H. Homma and M. Kimura (Hokkaido University)
Stephane Grévy : October 8, 2012 Unveiling the intruder deformed state in 34 Si 20 and few words about N=28 IFIN - Bucharest F. Rotaru.
Rotation and alignment of high-j orbitls in transfermium nuclei Dr. Xiao-tao He College of Material Science and Technology, Nanjing University of Aeronautics.
1 In-Beam Observables Rauno Julin Department of Physics University of Jyväskylä JYFL Finland.
Nuclear Structure and dynamics within the Energy Density Functional theory Denis Lacroix IPN Orsay Coll: G. Scamps, D. Gambacurta, G. Hupin M. Bender and.
Quadrupole collectivity in neutron-rich Cd isotopes Thorsten Kröll for the IS411/IS477/IS524 collaborations Work supported by BMBF (Nr. 06DA9036I and 05P12RDCIA),
Evolution of Nuclear Structure with the Increase of Neutron Richness – Orbital Crossing in Potassium Isotopes W. Królas, R. Broda, B. Fornal, T. Pawłat,
Core-excited states in 101 Sn Darek Seweryniak, ANL GS/FMA collaboration.
N = Z N=Z line coincides with doubly-magic core Single-particle states wrt 100 Sn core Neutron-proton correlations in identical orbitals Neutron-proton.
Coupling of (deformed) core and weakly bound neutron M. Kimura (Hokkaido Univ.)
Erosion of N=28 Shell Gap and Triple Shape Coexistence in the vicinity of 44 S M. KIMURA (HOKKAIDO UNIV.) Y. TANIGUCHI (RIKEN), Y. KANADA-EN’YO(KYOTO UNIV.)
Shell Model with residual interactions – mostly 2-particle systems Start with 2-particle system, that is a nucleus „doubly magic + 2“ Consider two identical.
Héloïse Goutte CERN Summer student program 2009 Introduction to Nuclear physics; The nucleus a complex system Héloïse Goutte CEA, DAM, DIF
Anomalous two-neutron transfer in neutron-rich Ni and Sn isotopes studied with continuum QRPA H.Shimoyama, M.Matsuo Niigata University 1 Dynamics and Correlations.
AGATA Physics Workshop Istanbul, Turkey May 4-7, 2010 G. Duchêne Deformation in N=40 nuclei G. Duchêne, R. Lozeva, C. Beck, D. Curien, F. Didierjean, Ch.
H.Sakurai Univ. of Tokyo Spectroscopy on light exotic nuclei.
Variational multiparticle-multihole configuration mixing approach
Deformations of sd and pf shell  hypernuclei with antisymmetrized molecular dynamics Masahiro Isaka (RIKEN)
Studies of hypernuclei with the AMD method Masahiro ISAKA Institute of Physical and Chemical Research (RIKEN) Focusing on 25  Mg, based on M. Isaka, M.
Nuclear and Radiation Physics, BAU, First Semester, (Saed Dababneh). 1 Extreme independent particle model!!! Does the core really remain inert?
July 29-30, 2010, Dresden 1 Forbidden Beta Transitions in Neutrinoless Double Beta Decay Kazuo Muto Department of Physics, Tokyo Institute of Technology.
Leuven - Mainz - ISOLDE collaboration at CERN
Héloïse Goutte CERN Summer student program 2009 Introduction to Nuclear physics; The nucleus a complex system Héloïse Goutte CEA, DAM, DIF
Variational approach to isospin symmetry breaking in medium mass nuclei A. PETROVICI Institute for Physics and Nuclear Engineering, Bucharest, Romania.
第十四届全国核结构大会暨第十次全国核结构专题讨论会
Shape evolution of highly deformed 75 Kr and projected shell model description Yang Yingchun Shanghai Jiao Tong University Shanghai, August 24, 2009.
S. L. Tabor – Florida State University ATLAS Users Meeting August 8, 2009 Sam Tabor - Florida State University Intruder states approaching the Island of.
Exotic neutron-rich nuclei
Coulomb breakup of 22 C and 31 Ne N. Kobayashi Department of Physics, Tokyo Institute of Technology.
Nuclear moments and charge radii of Mg isotopes from N=8 up to (and beyond) N=20 Univ. Mainz: M. Kowalska, R. Neugart K.U.Leuven: D. Borremans, S. Gheysen,
Satoru Sugimoto Kyoto University 1. Introduction 2. Charge- and parity-projected Hartree-Fock method (a mean field type model) and its application to sub-closed.
Time dependent GCM+GOA method applied to the fission process ESNT janvier / 316 H. Goutte, J.-F. Berger, D. Gogny CEA/DAM Ile de France.
g-ray spectroscopy of the sd-shell hypernuclei
Shape coexistence in the neutron- deficient Pb region: Coulomb excitation at REX-ISOLDE Liam Gaffney 1,2 Nele Kesteloot 2,3 1 University of the West of.
Spectroscopy studies around 78 Ni and beyond N=50 via transfer and Coulomb excitation reactions J. J. Valiente Dobón (INFN-LNL, Padova,Italy) A. Gadea.
Lecture 4 1.The role of orientation angles of the colliding nuclei relative to the beam energy in fusion-fission and quasifission reactions. 2.The effect.
Few-Body Models of Light Nuclei The 8th APCTP-BLTP JINR Joint Workshop June 29 – July 4, 2014, Jeju, Korea S. N. Ershov.
Rotational energy term in the empirical formula for the yrast energies in even-even nuclei Eunja Ha and S. W. Hong Department of Physics, Sungkyunkwan.
超重原子核的结构 孙 扬 上海交通大学 合作者:清华大学 龙桂鲁, F. Al-Khudair 中国原子能研究院 陈永寿,高早春 济南,山东大学, 2008 年 9 月 20 日.
Shell-model calculations for the IoI —a review from a personal point of view Yutaka Utsuno Advanced Science Research Center, Japan Atomic Energy Agency.
Masahiro Isaka (RIKEN)
Limits of stability: halo nuclei
Low energy nuclear collective modes and excitations
Emmanuel Clément IN2P3/GANIL – Caen France
Systematic study of Z = 83 nuclei: 193,194,195Bi
Satoshi Adachi Research Center for Nuclear Physics (RCNP),
Isospin Symmetry test on the semimagic 44Cr
Nuclear Chemistry CHEM 396 Chapter 4, Part B Dr. Ahmad Hamaed
Impurity effects in p-sd shell and neutron-rich L hypernuclei
Introduction Calculations for the N=7 isotones Summary
PHL424: Shell model with residual interaction
Nuclear Physics, JU, Second Semester,
Daisuke ABE Department of Physics, University of Tokyo
Rotation and alignment of high-j orbitls in transfermium nuclei
Shape-coexistence enhanced by multi-quasiparticle excitations in A~190 mass region 石跃 北京大学 导师:许甫荣教授
Presentation transcript:

Systematic study of the many- particle and many-hole states in and around the Island of Inversion - #N=Odd system - M. Kimura(Hokkaido)

Introduction: Island of Inversion Island of Inversion: N ~ 20 Ne, Na, Mg isotopes Topics: large deformation, mpmh config., shell gap quench N=21 isotone: 31 Ne(binding limit), 33 Mg Topics: spin-parity, p-wave halo, neutron orbital N=21 isotone Odd-mass(neutron) system reveals neutron-orbital, shape coexistence in the Island The last neutron particle (hole) orbital has strong influence on nuclear properties In N=21 isotone, 0f 7/2 and 0d 3/2 orbials take part in the game Island of Inversion

Theoretical Framework: AMD A-body Hamiltonian Parity projected Slater determinant Single particle wave packets Variational parameters Gogny D1S

Theoretical Framework: AMD Angular momentum projection GCM Generator Coordinate: quadrupole deformation  Hill-Wheeler eq.

Energy curves in and around the Island ph configuration depends on neutron # Relative energy between ph states depends on the proton number The Island

Spectrum of 32 Mg V. Tripathi, et. al., PRC (2008).

Results: 0 + and 2 + states (N=20 isotones) Strongly deformed 2p2h takes over the ground state Note that 0p0h, 2p2h and 4p4h appear in the Island 4p4h (more deformed) also participates in. Some experimental evidences

Results: 0 + and 2 + states (Z=10,12 isotopes) 2p2h dominates in N=20, 22 system 4p4h (4h  )appears only in N=20 isotopes Intermediate character of N=18 isotopes Precursor in N=18 system

Results: 1 - and 3 - states (N=20 isotones) Great reduction of 3p3h energy 1p1h is not so sensitive to the proton number

Results: 1 - and 3 - states (Z=10,12 isotopes) Great reduction of 1h  excitation energy Due to the reduction, de-excitation is also possible in the island Precursor in N=18 system

Introduction: Particle Hole Config. (N=19 System) 1p-removal from 32 Al D. Miller, et.al.,Phys. Rev. C 79, (2009) 31 Mg 0p1h 1p2h 2p3h 3p4h M. K. Phys.Rev. C 75, (2007)

J     -decays 33 Na(N=22,g.s.) → 33 Mg(g.s.) 33 Mg(g.s.) → 33 Al(N=20, g.s.) J    magnetic-moment:  =  N 1n-removal: p 3/2 S. Nummela, et. al., PRC64, (2001) V. Tripathi, et. al., PRL101, (2008) D. T. Yordarov, et. al., PRL99, (2007) R. Kanungo, et. Al., PLB685, 253 (2010) Introduction: Spin-parity of 33 Mg(N=21)

Introduction: 1n Halo of 31 Ne(N=21) 1n-Removal Exp. : Large cross section : Observed large cross section can be explained with small Sn and l=1,2 Large Reaction cross section M. Takechi, et. al., Nucl. Phys. A 834, (2010), 412 T. Nakamura, et. al., PRL103, (2009) Halo?

Results: Energy Curve and PH Config. of 33 Mg 33 Mg 1p0h 2p1h3p2h 4p3h 2p1h1p0h3p2h4p3h

Introduction: Particle Hole Config. (N=21 System) 33 Mg 1p0h 2p1h 3p2h 4p3h

Results: Spectrum of 33 Mg Consistent with magnetic moment exp. AMD underestimates number of very low-lying states Sn=3.2MeV

Results:  -decay and J  assignment 33 Na(4p2h) feeds 4p3h config. 33 Na(4p2h) 33 Mg*(4p3h)

Results: B(E2) of 33 Mg Coulomb Excitation Exp. : B.V. Pritychenko, et. al., PRC65, (R) (2002). Large cross section for 485keV state Authors assumed J  =5/2+ for the ground state (no information was available at that time except for  -decay data that suggested positive parity) Large cross section does not contradict to AMD (Further exp. is required.)

Results: Spectrum of 31 Ne Sn=250keV Same J  with 33 Mg, but much smaller Sn 3/2+ is almost degenerated (Ex=120keV)

Summary and Plan Summary 33 Mg has negative-parity ground state with J=3/2 AMD agrees with magnetic moment and COULEX experiments, but contradict to  -decay  -decay of 33 Na should feeds 4p3h config. of 33 Mg 31 Ne also has negative-parity ground state with J=3/2 and very small Sn. J=3/2- is almost degenerated. Plans Small Sn, but no Halo ! (fault of AMD, RGM calc. to see it) p-n interaction dependence of level-ordering