Modern description of nuclei far from stability

Modern description of nuclei far from stability
Covariant density functional theory of the dynamics of nuclei far from stability Barcelona, Dec. 10, 2007 Peter Ring Universidad Autónoma de Madrid Technische Universität München Istanbul, July 2/3, 2008 Isotopen-Tafel mit Feldern einbauen Peter Ring Technische Universität München Summer School IV on Nuclear Collective Dynamics

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Motivation Density Functional Theory The Nuclear Density Functional Covariant Density Functional Ground state properties Nuclear dynamics and excitations Outlook Summer School IV on Nuclear Collective Dynamics

Summer School IV on Nuclear Collective Dynamics
Pb proton number Z Au Fe neutron number N H neutron number N Summer School IV on Nuclear Collective Dynamics

magic numbers ? Summer School IV on Nuclear Collective Dynamics

Forces acting in the nucleus:
the Coulomb force repels the protons the strong interaction ("nuclear force") causes binding is stronger for pn-systems than nn-systems neutrons alone form no bound states exception: neutronen stars (gravitation!) e the weak interaction causes β-decay: n p ν - Summer School IV on Nuclear Collective Dynamics

the nucleon-nucleon interaction:
distance > 1 fm attractive π-meson 1 fm distance < 0.5 fm ? repulsive three-body forces ? Summer School IV on Nuclear Collective Dynamics

binding energy per particle
sun energy He H U Fe A fusion fission reactor energy B 8 (MeV) particle number Summer School IV on Nuclear Collective Dynamics

β+ β- N-Z β+ decay β- decay Summer School IV on Nuclear Collective Dynamics

β+ β- N-Z Summer School IV on Nuclear Collective Dynamics

the nuclear density: ρ(r)
simplified representation: ρ r ρ=1.6 nucleons/fm3 Summer School IV on Nuclear Collective Dynamics

proton and neutron densities
or? n p ρ ρ p n r r ρ r small neutron excess large neutron excess Summer School IV on Nuclear Collective Dynamics

Nuclei far from stability: what can we learn?
the origin of more than half of the elements with Z>30 constraints on effective nuclear interactions evolution of shell structure reduction of the spin-orbit interaction properties of weakly-bound and open quantum systems exotic modes of collective excitations (pygmy, toroidal resonances) possible new forms of nuclei (molecular states, bubble nuclei, neutron droplets...) asymmetric nuclear matter equation of state and the link to neutron stars - applications in astrophysics Summer School IV on Nuclear Collective Dynamics

Abundancies of elements in the solar system
Au Summer School IV on Nuclear Collective Dynamics

synthesis of heavy elements beyond Fe
neutron capture and successive β-decay: (N,Z+1) e- n (N,Z) (N+1,Z) Z+1 Z N N+1 Summer School IV on Nuclear Collective Dynamics

Study of Nucleosynthesis r process Summer School IV on Nuclear Collective Dynamics

What do the astrophysicists need ?
nuclear masses (bindung energies – Q-values) equation of state (EOS) of nuclear matter: E(ρ) isospin dependence E(ρp, ρn) nuclear matrix elements (life times of β-decay ..) cross section for neutron or electron capture …. fission probabilities cross sections for neutrino reactions ….. Summer School IV on Nuclear Collective Dynamics

nuclei and QCD? effective forces in the nucleus QCD NN- forces in the vacuum Scales: GeV keV Summer School IV on Nuclear Collective Dynamics

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density functional theory:
theorem of Hohenberg und Kohn: Hohenberg Kohn Summer School IV on Nuclear Collective Dynamics

Many-body system in an external field U(r):
We consider now a realistic manybody system in an external field U(r) and a two-body interaction V(ri,rk). The total energy Etot of the system depends on U(r). It is a functional of U(r): in the same way we obtain the density: Inverting this relation we can introduce a Legendre transformation replacing the independent function U(r) by the density ρ(r): Summer School IV on Nuclear Collective Dynamics

Decomposition of HK-functional
In practical applications the functional EHK[ρ] is decomposed into three parts: The Hartree term is simple: The non interacting part: The exchange-correlation part is the rest: Exc is less important and often approximated, but for modern calculations it plays a essential rule. Summer School IV on Nuclear Collective Dynamics

Thomas Fermi Thomas Fermi approximation:
Thomas and Fermi used the local density approximation (LDA) in order to get an analytical expression for the non-interacting term. They calculated the kinetic energy density of a homogeneous system with constant density ρ where γ is the spin/isospin degeneracy. Using this expression at the local density they find: This is not very good (molecules are never bound) and therefore one added later on gradient terms containing ∇ρ and Δρ. This method is called Extended Thomas Fermi (ETF) theory. However, these are all asymptotic expansions and one always ends up with semi-classical approximations. Shell effects are never included. Summer School IV on Nuclear Collective Dynamics

Example for Thomas-Fermi approximation:
exact Thomas-Fermi appr. Summer School IV on Nuclear Collective Dynamics

Kohn-Sham theory: Kohn-Sham theory In order to reproduce shell structure Kohn and Sham introduced a single particle potential Veff(r), which is defined by the condition, that after the solution of the single particle eigenvalue problem the density obtained as is the exact density Obviously to each density ρ(r) there exist such a potential Veff(r). The non interacting part of the energy functional is given by: and obviously we have: Summer School IV on Nuclear Collective Dynamics

limitations of exact density functionals:
in practice formally exact Hohenberg-Kohn: Kohn-Sham: Skyrme: Gogny: no shell effects no l•s, no pairing no config.mixing generalized mean field: no configuration mixing, no two-body correlations local density: kinetic energy density: pairing density: twobody density: Summer School IV on Nuclear Collective Dynamics

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Density functional theory
Density functional theory in nuclei: Density functional theory 1) The interaction is not well known and very strong 2) More degrees of freedom: spin, isospin, relativistic, pairing 3) Nuclei are selfbound systems. The exact density is a constant. ρ(r) = const Hohenberg-Kohn theorem is true, but useless 4) ρ(r) has to be replaced by the intrinsic density: 5) Density functional theory in nuclei is probably not exact, but a very good approximation. Summer School IV on Nuclear Collective Dynamics

Density functional theory in nuclei
D.Brink D.Vauterin Skyrme Slater determinant density matrix Mean field: Eigenfunctions: Interaction: Extensions: Pairing correlations, Covariance Relativistic Hartree Bogoliubov (RHB) Summer School IV on Nuclear Collective Dynamics

General properties of self-consistent mean field theories:
the nuclear energy functional is so far phenomenological and not connected to any NN-interaction. it is expressed in terms of powers and gradients of the nuclear ground state density using the principles of symmetry and simplicity The remaining parameters are adjusted to characteristic properties of nuclear matter and finite nuclei Virtues: (i) the intuitive interpretation of mean fields results in terms of intrinsic shapes and of shells with single particle states (ii) the full model space is used: no distinction between core and valence nucleons, no need for effective charges (iii) the functional is universal: it can be applied to all nuclei throughout the periodic chart, light and heavy, spherical and deformed Summer School IV on Nuclear Collective Dynamics

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Dirac equation in atoms:
Coulomb potential: (r) with magnetic field: magnetic potential: (r) Summer School IV on Nuclear Collective Dynamics

Dirac equation in nuclei:
scalar potential vector potential (time-like) vector potential (space-like) vector space-like corresponds to magnetic potential (nuclear magnetism) is time-odd and vanishes in the ground state of even-even systems Summer School IV on Nuclear Collective Dynamics

Relativistic potentials
continuum V-S ≈ 50 MeV Fermi sea 2m* ≈ 1200 MeV 2m ≈ 1800 MeV Dirac sea V+S ≈ 700 MeV Summer School IV on Nuclear Collective Dynamics

Elimination of small components:
for Summer School IV on Nuclear Collective Dynamics

Why covariant ? no relativistic kinematic necessary: non-relativistic DFT works well 3) technical problems: no harmonic oscillator no exact soluble models double dimension huge cancellations V-S no variational method conceptual problems: treatment of Dirac sea no well defined many-body theory Summer School IV on Nuclear Collective Dynamics

Why covariant Why covariant? Large spin-orbit splitting in nuclei Large fields V≈350 MeV , S≈-400 MeV Success of Relativistic Brueckner Success of intermediate energy proton scatt. relativistic saturation mechanism consistent treatment of time-odd fields Pseudo-spin Symmetry Connection to underlying theories ? As many symmetries as possible Coester-line Summer School IV on Nuclear Collective Dynamics

Walecka model Walecka model Nucleons are coupled by exchange of mesons through an effective Lagrangian (EFT) (J,T)=(0+,0) (J,T)=(1-,0) (J,T)=(1-,1) Sigma-meson: attractive scalar field Omega-meson: short-range repulsive Rho-meson: isovector field Summer School IV on Nuclear Collective Dynamics

Lagrangian density Lagrangian free Dirac particle free meson fields free photon field interaction terms Parameter: meson masses: mσ, mω, mρ meson couplings: gσ, gω, gρ interaction terms Summer School IV on Nuclear Collective Dynamics

Equations of motion equations of motion
for the nucleons we find the Dirac equation No-sea approxim. ! for the mesons we find the Klein-Gordon equation Summer School IV on Nuclear Collective Dynamics

Static limit (with time reversal invariance)
for the nucleons we find the static Dirac equation No-sea approxim. ! for the mesons we find the Helmholtz equations Summer School IV on Nuclear Collective Dynamics

Relativistic saturation mechanism:
We consider only the σ-field, the origin of attraction its source is the scalar density for high densities, when the collapse is close, the Dirac gap ≈2m* decreases, the small components fi of the wave functions increase and reduce the scalar density, i.e. the source of the σ-field, and therefore also scalar attraction. In the non-relativistic case, Hartree with Yukawa forces would lead to collapse Summer School IV on Nuclear Collective Dynamics

Equation of state (EOS): EOS-Walecka σω-model J.D. Walecka, Ann.Phys. (NY) 83, (1974) 491 Summer School IV on Nuclear Collective Dynamics

Effective density dependence:
non-linear potential: NL1,NL3.. Boguta and Bodmer, NPA 431, 3408 (1977) density dependent coupling constants: R.Brockmann and H.Toki, PRL 68, 3408 (1992) S.Typel and H.H.Wolter, NPA 656, 331 (1999) T. Niksic, D. Vretenar, P. Finelli, and P. Ring, PRC 56 (2002) g  g(r(r)) DD-ME1,DD-ME2 Summer School IV on Nuclear Collective Dynamics

Point-Coupling Models
σ ω δ ρ J=0, T=0 J=1, T=0 J=0, T=1 J=1, T=1 Point-coupling model Manakos and Mannel, Z.Phys. 330, 223 (1988) Bürvenich, Madland, Maruhn, Reinhard, PRC 65, (2002) Summer School IV on Nuclear Collective Dynamics

Lagrangian density for point coupling
free Dirac particle interaction terms interaction terms Parameter: point couplings: Gσ, Gω, Gδ , Gρ, derivative terms: Dσ photon field Summer School IV on Nuclear Collective Dynamics

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Nuclear matter equation of state
EOS for DD-ME2 Neutron Matter Summer School IV on Nuclear Collective Dynamics

Symmetry energy Symmetry energy
saturation density empirical values: 30 MeV £ a4 £ 34 MeV 2 MeV/fm3 < p0 < 4 MeV/fm3 -200 MeV < DK0 < -50 MeV Lombardo Summer School IV on Nuclear Collective Dynamics

Summer School IV on Nuclear Collective Dynamics

Conclusions part I: Conclusions I density functional theory is in principle exact microscopic derivation of E(ρ) very difficult Lorentz symmetry gives essential constraints - large spin orbit splitting - relativistic saturation - unified theory of time-odd fields 4) in realistic nuclei one needs a density dependence - non-linear coupling of mesons - density dependent coupling-parameters 5) modern parameter sets (7 parameter) provide excellent description of ground state properties - binding energies (1 ‰) - radii (1 %) - deformation parameters 6) pairing effects are non-relativisitic Summer School IV on Nuclear Collective Dynamics

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Time dependent mean field theory:
TDRMF: Eq. Time dependent mean field theory: No-sea approxim. ! and similar equations for the ρ- and A-field Summer School IV on Nuclear Collective Dynamics

Monopole motion Breathing mode: 208Pb K∞=211 K∞=271 K∞=355 Interaction: Summer School IV on Nuclear Collective Dynamics

Relativistic RPA for excited states Small amplitude limit:
RRPA Relativistic RPA for excited states drph, drah Small amplitude limit: ground-state density drhp, drha RRPA matrices: Interaction: the same effective interaction determines the Dirac-Hartree single-particle spectrum and the residual interaction Summer School IV on Nuclear Collective Dynamics

2+-excitation in Sn-isotopes:
Ansari-Sn A. Ansari, Phys. Lett. B (2005) Summer School IV on Nuclear Collective Dynamics

Relativistic (Q)RPA calculations of giant resonances Sn isotopes: DD-ME2 effective interaction + Gogny pairing Isovector dipole response protons neutrons Isoscalar monopole response Summer School IV on Nuclear Collective Dynamics

Isoscalar Giant Monopole: IS-GMR
The ISGMR represents the essential source of experimental information on the nuclear incompressibility Blaizot-concept: ρ(t) = ρ0 + δρ(t) constraining the nuclear matter compressibility RMF models reproduce the experimental data only if 250 MeV £ K0 £ 270 MeV T. Niksic et al., PRC 66 (2002) Summer School IV on Nuclear Collective Dynamics

Isovector Giant Dipole: IV-GDR IV-GDR
the IV-GDR represents one of the sources of experimental informations on the nuclear matter symmetry energy constraining the nuclear matter symmetry energy the position of IV-GDR is reproduced if 32 MeV £ a4 £ 36 MeV T. Niksic et al., PRC 66 (2002) Summer School IV on Nuclear Collective Dynamics

Soft dipole modes and neutron skin

Exp: pygmy O Summer School IV on Nuclear Collective Dynamics

Pygmy: O-chain Evolution of IV dipole strength in Oxygen isotopes RHB + RQRPA calculations with the NL3 relativistic mean-field plus D1S Gogny pairing interaction. Transition densities What is the structure of low-lying strength below 15 MeV ? Effect of pairing correlations on the dipole strength distribution Summer School IV on Nuclear Collective Dynamics

Pygmy: 132-Sn Mass dependence of GDR and Pygmy dipole states in Sn isotopes. Evolution of the low-lying strength. Isovector dipole strength in 132Sn. Nucl. Phys. A692, 496 (2001) GDR Distribution of the neutron particle-hole configurations for the peak at 7.6 MeV (1.4% of the EWSR) Pygmy state exp Summer School IV on Nuclear Collective Dynamics

Vibrations in deformed nuclei
K J T=0 T=1 Goldstone modes Translations: Rotations: Gauge rotations: Giant dipole modes: Scissor modes: K=0- K=1- K=0- K=1- K=1+ K=1+ K=0+ Summer School IV on Nuclear Collective Dynamics

isovector-dipole response in 100Mo
IV-GDR in 100Mo isovector-dipole response in 100Mo IV-GDR ρ0 + δρ(t) K=0- K=1- Summer School IV on Nuclear Collective Dynamics

pygmy modes in 100Mo Summer School IV on Nuclear Collective Dynamics

response of the nucleus to an incoming particle
scattering at a single nucleon excitation of the entire nucleus we need the nuclear spectrum Summer School IV on Nuclear Collective Dynamics

neutrino reactions e- ν (N,Z)→(N-1,Z+1) W- p e- n + spin-isospin-wave ν Summer School IV on Nuclear Collective Dynamics

beta-decay e- ν - (N,Z)→(N-1,Z+1) W± e- p p ν - e- ν - + n n spin-isospin-wave Summer School IV on Nuclear Collective Dynamics

Spin-Isospin Resonances: IAR - GTR
Z,N Z+1,N-1 spin flip s isospin flip t p n Summer School IV on Nuclear Collective Dynamics

Spin-Isospin Resonances: IAR - GTR
ISOBARIC ANALOG AND GAMOW-TELLER RESONANCES (RQRPA) ISOSPIN-FLIP EXCITATIONS S=0 T=1 J = 0+ S=1 T=1 J = 1+ SPIN-FLIP & ISOSPIN-FLIP EXCITATIONS PR C69, (2004) Summer School IV on Nuclear Collective Dynamics

G. Martinez-Pinedo and K. Langanke,
β-decay β-decay: Sn,Te G. Martinez-Pinedo and K. Langanke, PRL 83, 4502 (1999) h9/2->h11/2 T. Niksic et al, PRC 71, (2005) Summer School IV on Nuclear Collective Dynamics

neutrino-nucleus reactions
3- 2+ 2- 1- 0+ 1+ 0+ ZXN Z+1XN-1 important: 1. we learn about the reaction mechanism 2. we calculate the detector response for neutrino reactions 3. neutrinos play also a role in nuclear synthesis so far there exist ony few data: → deuteron, 12C, 56Fe Summer School IV on Nuclear Collective Dynamics

Cross section averaged over supernova neutrino flux
Supernova neutrino flux is given by Fermi-Dirac spectrum 4 3 2 1 5 a T [MeV] Cross section averaged over Supernova neutrino flux Summer School IV on Nuclear Collective Dynamics

Distribution of cross section over multipolarities
DISTRIBUTION OF CROSS SECTIONS OVER MULTIPOLARITIES distribution of cross sections over multipolarities is strongly model dependent Summer School IV on Nuclear Collective Dynamics

RHB-RQRPA neutrino-nucleus 56Fe cross section

Cross section (νe,e-) averaged over supernova neutrino flux
CROSS SECTIONS AVERAGED OVER NEUTRINO FLUX Cross section (νe,e-) averaged over supernova neutrino flux muon decay at rest ne flux Summer School IV on Nuclear Collective Dynamics

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construction areas Is density functional theory exact in self-bound systems as nuclei? beyond mean field tensor-forces and single particle stucture? improvement of the functional derivation of the functional from the NN-force ? Summer School IV on Nuclear Collective Dynamics

Colaborators: A. Ansari (Bubaneshwar) G. A. Lalazissis (Thessaloniki) D. Vretenar (Zagreb) T. Niksic (Zagreb) N. Paar (Zagreb) D. Pena Arteaga A. Wandelt Summer School IV on Nuclear Collective Dynamics

References Literature Books on Nuclear Structure Theory A. Bohr and B. Mottelson, “Nuclear Structure, Vol. I and II” P. Ring and P. Schuck, “The Nuclear Many-Body Problem” J.-P. Blaizot and G. Ripka, “Quantum Theory of Finite Systems” V.G. Soloviev, “Theory of Atomic Nuclei” Review Articles on Covariant Density Functional Theory B. D. Serot and J. D. Walecka, Adv. Nucl. Phys. 16, 1 (1986) P.-G. Reinhard, Rep. Prog. Phys. 52, 439 (1989) B. D. Serot, Rep. Prog. Phys. 55, 1855 (1992) P. Ring, Progr. Part. Nucl. Phys. 37, 193 (1996) B. D. Serot and J. D. Walecka, Int. J. Mod. Phys. E6, 515 (1997) Lecture Notes in Physics 641 (2004), “Extended Density Functionals in Nuclear Structure” D.Vretenar, Afanasjev, Lalazissis, P.Ring, Phys.Rep. 409 ('05) 101 Summer School IV on Nuclear Collective Dynamics

Computer Programs Computer Programs H. Berghammer et al, Comp. Phys. Comm. 88, 293 (1995), “Computer Program for the Time-Evolution of Nuclear Systems in Relativistic Mean Field Theory.” W. Pöschl et al, Comp. Phys. Comm. 99, 128 (1996), “Application of the Finite Element Method in self-consistent RMF calculations.” W. Pöschl et al, Comp. Phys. Comm. 101, 295 (1997), “Applica- tion of the Finite Element Method in RMF theory: the spherical Nucleus.” W. Pöschl et al, Comp. Phys. Comm. 103, 217 (1997), “Relativistic Hartree-Bogoliubov Theory in Coordinate Space: Finite Element Solution in a Nuclear System with Spherical Symmetry.” P. Ring, Y.K. Gambhir and G.A. Lalazissis, 105, 77 (1997), “Computer Program for the RMF Description of Ground State Properties of Even-Even Axially Deformed Nuclei .” Summer School IV on Nuclear Collective Dynamics

Modern description of nuclei far from stability

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