Gogny-TDHFB calculation of nonlinear vibrations in 44,52 Ti Yukio Hashimoto Graduate school of pure and applied sciences, University of Tsukuba 1.Introduction.

Slides:

Advertisements

Similar presentations

Giant resonances, exotic modes & astrophysics

Advertisements

Valence shell excitations in even-even spherical nuclei within microscopic model Ch. Stoyanov Institute for Nuclear Research and Nuclear Energy Sofia,

電気的に励起された岩田順敬 ( 東大理 ) Cedric Simenel (CEA/Saclay) 原子核の時間発展 Thanks to: 大塚孝治 ( 東大理、東大 CNS 、理研 ) Michael Bender (CEA/Saclay)

RIKEN, March 2006: Mean field theories and beyond Peter Ring RIKEN, March 20, 2006 Technical University Munich RIKEN-06 Beyond Relativistic.

CEA DSM Irfu 14 Oct Benoît Avez - [Pairing vibrations with TDHFB] - ESNT Workshop1 Pairing vibrations study in the Time-Dependent Hartree-Fock Bogoliubov.

1 Di-Neutron Correlation in Soft Octupole Excitations of Medium-Mass Nuclei near Drip-Line Y. Serizawa and M. Matsuo Niigata Univ.

12 June, 2006Istanbul, part I1 Mean Field Methods for Nuclear Structure Part 1: Ground State Properties: Hartree-Fock and Hartree-Fock- Bogoliubov Approaches.

Mean-field calculation based on proton-neutron mixed energy density functionals Koichi Sato (RIKEN Nishina Center) Collaborators: Jacek Dobaczewski (Univ.

Systematic calculations of electric dipole response with fully self-consistent Skyrme-RPA University of Aizu-JUSTIPEN-EFES Symposium on "Cutting-Edge Physics.

Spin polarization phenomena in dense nuclear matter Alexander Isayev Kharkov Institute of Physics and Technology Ukraine.

Continuum QRPA calculation with the Skyrme effective force Niigata University Kazuhito Mizuyama Masayuki Matsuo & Yasuyoshi Serizawa.

John Daoutidis October 5 th 2009 Technical University Munich Title Continuum Relativistic Random Phase Approximation in Spherical Nuclei.

Forces for extensions of mean-field PhD Thesis Marlène Assié Denis Lacroix (LPC Caen), Jean-Antoine Scarpaci (IPN Orsay)  Extensions of mean-field ? 

Single Particle Energies

Emilian Nica Texas A&M University Advisor: Dr.Shalom Shlomo

CEA Bruyères-le-Châtel Kazimierz sept 2005, Poland Variational Multiparticle-Multihole Mixing with the D1S Gogny force N. Pillet (a), J.-F. Berger (a),

Crystal Lattice Vibrations: Phonons

Etat de lieux de la QRPA = state of the art of the QRPA calculations G. Colò / E. Khan Espace de Structure Nucléaire Théorique SPhN, Saclay, January 11-12,

Black hole production in preheating Teruaki Suyama (Kyoto University) Takahiro Tanaka (Kyoto University) Bruce Bassett (ICG, University of Portsmouth)

Tomohiro Oishi 1,2, Markus Kortelainen 2,1, Nobuo Hinohara 3,4 1 Helsinki Institute of Phys., Univ. of Helsinki 2 Dept. of Phys., Univ. of Jyvaskyla 3.

1 The Random Phase Approximation in Nuclear Physics  Lay out of the presentation: 1. Linear response theory: a brief reminder 2. Non-relativistic RPA.

XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept , Kazimierz Dolny, Poland Self-Consistent.

Effects of self-consistence violations in HF based RPA calculations for giant resonances Shalom Shlomo Texas A&M University.

Angular Momentum Projection in TDHF Dynamics : application to Coulomb excitation and fusion C. Simenel 1,2 In collaboration with M. Bender 2, T. Duguet.

Nuclear Structure and dynamics within the Energy Density Functional theory Denis Lacroix IPN Orsay Coll: G. Scamps, D. Gambacurta, G. Hupin M. Bender and.

The calculation of Fermi transitions allows a microscopic estimation (Fig. 3) of the isospin mixing amount in the parent ground state, defined as the probability.

E1 strength distribution in even-even nuclei studied with the time-dependent density functional calculations Takashi NAKATSUKASA Theoretical Nuclear Physics.

Isovector scenario for nuclei near the N=Z line Anatoli Afanasjev S. Frauendorf Kai Neergard J. Sheikh.

Nuclear Models Nuclear force is not yet fully understood.

Isospin mixing and parity- violating electron scattering O. Moreno, P. Sarriguren, E. Moya de Guerra and J. M. Udías (IEM-CSIC Madrid and UCM Madrid) T.

Coupling of (deformed) core and weakly bound neutron M. Kimura (Hokkaido Univ.)

ESNT Saclay February 2, Structure properties of even-even actinides at normal- and super-deformed shapes J.P. Delaroche, M. Girod, H. Goutte, J.

NSDD Workshop, Trieste, February 2006 Nuclear Structure (I) Single-particle models P. Van Isacker, GANIL, France.

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.

Effects of Brown-Rho scaling in nuclear matter, neutron stars and finite nuclei T.T.S. Kuo ★ ★ Collaborators: H. Dong (StonyBrook), G.E. Brown (StonyBrook)

Unitarity potentials and neutron matter at unitary limit T.T.S. Kuo (Stony Brook) H. Dong (Stony Brook), R. Machleidt (Idaho) Collaborators:

T=0 Pairing in Coordinate space Workshop ESNT, Paris Shufang Ban Royal Institute of Technology (KTH) Stockholm, Sweden.

NEUTRON SKIN AND GIANT RESONANCES Shalom Shlomo Cyclotron Institute Texas A&M University.

July 29-30, 2010, Dresden 1 Forbidden Beta Transitions in Neutrinoless Double Beta Decay Kazuo Muto Department of Physics, Tokyo Institute of Technology.

N. Schunck(1,2,3) and J. L. Egido(3)

Some aspects of chaos in TDHF …and a bit of laser-induced fission P. D. Stevenson, University of Surrey, UK …and a bit of laser-induced fission P. D. Stevenson,

F. C HAPPERT N. P ILLET, M. G IROD AND J.-F. B ERGER CEA, DAM, DIF THE D2 GOGNY INTERACTION F. C HAPPERT ET AL., P HYS. R EV. C 91, (2015)

The i 13/2 Proton and j 15/2 Neutron Orbital and the SD Band in A~190 Region Xiao-tao He En-guang Zhao En-guang Zhao Institute of Theoretical Physics,

Couplage de phonons = state of the art of “extended” RPA calculations G. Colò Espace de Structure Nucléaire Théorique SPhN, Saclay, January 11-12, 2005.

Nuclear density functional theory with a semi-contact 3-body interaction Denis Lacroix IPN Orsay Outline Infinite matter Results Energy density function.

Variational Multiparticle-Multihole Configuration Mixing Method with the D1S Gogny force INPC2007, Tokyo, 06/06/2007 Nathalie Pillet (CEA Bruyères-le-Châtel,

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.

Congresso del Dipartimento di Fisica Highlights in Physics –14 October 2005, Dipartimento di Fisica, Università di Milano Contribution to nuclear.

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.

Theoretical Nuclear Physics Laboratory

Continuum quasiparticle linear response theory using the Skyrme functional for exotic nuclei University of Jyväskylä Kazuhito Mizuyama, Niigata University,

Pairing Correlation in neutron-rich nuclei

The role of isospin symmetry in medium-mass N ~ Z nuclei

Open quantum systems.

Nuclear Structure Tools for Continuum Spectroscopy

The Isovector Giant Quadrupole Resonance & Nuclear Matter

Structure and dynamics from the time-dependent Hartree-Fock model

Low energy nuclear collective modes and excitations

Microscopic studies of the fission process

Description of t-band in 182Os with HFB+GCM

The continuum time-dependent Hartree-Fock method for Giant Resonances

Self-consistent theory of stellar electron capture rates

Hiroshi MASUI Kitami Institute of Technology

Kazuo MUTO Tokyo Institute of Technology

A self-consistent Skyrme RPA approach

Kyorin University Mitsuru Tohyama

Stability of g- and s-bands in 182Os in three-dimensional cranked HFB

V.V. Sargsyan, G.G. Adamian, N.V.Antonenko

Department of Physics, Sichuan University

Presentation transcript:

Gogny-TDHFB calculation of nonlinear vibrations in 44,52 Ti Yukio Hashimoto Graduate school of pure and applied sciences, University of Tsukuba 1.Introduction 2.TDHFB equation 3.Linear region 4-1. Nonlinear region (vibration type) 4-2. Nonlinear region (relaxation type) 5. summary

1. Introduction ☆ random phase approximation (RPA) on a large scale T. Inakura, from “Report of KEK Ohgata Simulation Program (2010)” ☆ S. Ebata et al., Phys. Rev. C 82 (2010), “canonical-basis TDHFB” with Skyrme force ☆ in this talk, Gogny force is used in TDHFB calculations Gogny force: ph channel  pp channel role of pairing correlation in vibration / relaxation

2. TDHFB equation

Equations of motion of matrices U & V see Ring & Schuck

Coulomb part is NOT included Gogny-D1S ・basis function：three-dimensional harmonic oscillator wave functions ・space： Gauss part density dependent part L-S part

Q 0 ： matrix representation of multipole operator initial U & V HFB ground state U, V initial conditions: ・ Q 20 type impulse on ground state （ impulse type ）・ constrained state with quadrupole operator （ constraint type ）

Energy conservation tdhf

3. Linear region

Example: 20 O quadrupole oscillation (small amplitude)

＊ 34 – 38 Mg quadrupole (K=0) mode ＊ 18– 22 O quadrupole mode ＊ 44,50,52,54 Ti quadrupole mode

4-1.Nonlinear region (oscillation type)

quadrupole oscillation and pairing 52 Ti prolateoblate pairing is zero

HF “pocket” initial conditions

52 Ti

occupation probability in orbital(k) UVUV () k k definition ： HFB matrix α ： numerical basis label

initial condition: Q20 = 0 fm^2 (impulse) initial condition: Q20 = 140 fm^2 (constraint)

initial condition: Q20 = 140 fm^2 initial condition: Q20 = 140 fm^2 initial condition: Q20 = 0 fm^2 (impulse) initial condition: Q20 = fm^2

( f7/2 members in initial stage) quadrupole moment (fm^2) single-particle energies vs Q time （ fm ） 44 Ti vibration Fermi energy

( f7/2 members in initial stage) quadrupole moment (fm^2) single-particle energies vs Q time （ fm ）

occupation probability p(k) (protons) Time (fm) HFB energies (MeV) HFB eigen energies (MeV)

4-2. Nonlinear region (relaxation type)

Q20 (fm ) 2 44 Ti Energy vs Q20 Energy (MeV) Time (fm) occupation probabilities p(k) ( neutron, minus parity) 0

time （ fm ） single particle energy （ MeV ） occupation probability p(k) 44 Ti relaxation of quadrupole oscillation （） occupation probability p(k) (protons) time （ fm ） quadrupole moment fm 2 Fermi energy

time （ fm ） single particle energy （ MeV ） occupation probability p(k) 44 Ti relaxation of quadrupole oscillation （） occupation probability p(k) (protons) time （ fm ） quadrupole moment fm 2

summary 1.(small amplitude case) RPA linear response  strength functions 2. (nonlinear case) i) long period oscillation accompanied with “adiabatic” configuration around single-particle level crossing region ii) relaxation together with adiabatic configuration across single-particle level crossing