Equazione di stato di materia nucleare : dai nuclei alle stelle compatte Fiorella Burgio (INFN Sezione di Catania) in collaborazione con Alessandro Drago.

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Presentation transcript:

Equazione di stato di materia nucleare : dai nuclei alle stelle compatte Fiorella Burgio (INFN Sezione di Catania) in collaborazione con Alessandro Drago (Università di Ferrara) Incontro Nazionale di Fisica Nucleare, Catania, Novembre 2012

EoS : any non-trivial relation between thermodynamic variables characterizing the matter, e.g. What is an Equation of State (EoS) ? VIRGO LNS GANIL Experiments Observations NICA 2

The EoS : where do we stand ? Droplet Model : if A ->∞ and N=Z, neglecting Coulomb terms Nuclear Incompressibility Symmetry energy L and K sym parameters characterizing the density dependence of the symmetry energy around the saturation point 3 In the vicinity of the saturation point ρ 0 for symmetric matter, the binding energy is usually expanded as I = (N – Z)/A

Nuclear Incompressibility for symmetric matter K In radial oscillations induced by α-particles scattering : A soft EoS at density close to the saturation value is preferred. Results are confirmed also by experiments on K + multiplicity in HIC 4 ρ=ρ 0

Kaon production in heavy ion collisions Kaons probe the dense nuclear medium K − N interaction not well known K + produced by : Simulations must include nucleon excitations and must be relativistic. Production rate dependent on the maximal density > compressibility. Experimental data by the KaoS and FOPI Collaborations : Double ratio : multiplicity per mass number for C+C collisions and Au+Au collisions at 0.8 AGeV and 1.0 AGeV. Largest density explored : ρ ≈ 2-3 ρ 0 Only calculations with a compression 180 ≤ K N ≤ 250 MeV can describe the data (Fuchs, 2001) Sturm et al, PRL 2001 The nuclear equation of state up to 2-3ρ 0 is SOFT ! 5

Transverse flow measurements in Au + Au collisions at E/A=0.5 to 10 GeV Pressure determined from simulations based on the Boltzmann-Uehling Uhlenbeck transport theory Science 298, 1592 (2002) Flow data exclude very repulsive equations of state, very soft EoS with phase transitions at ρ < 3ρ 0 do not exclude a phase transition to quark matter at higher density 6

7 Steinheimer & Bleicher, 2012 Neutron matter : Large uncertainty in the symmetry energy at high density It is found that the sound velocity has a local minimum (indicating a softest point in the equation of state, EoS) at √s NN =4-9 GeV, an energy scale accessible at the FAIR as well as the RHIC-Beam Energy Scan (RHIC-BES). This softening of the EoS is compatible with the formation of a QGP at the onset of deconfinement.

Importance of S and its slope L Lattimer & Lim, arXiv: Danielewicz, private communication Expected neutrino signal from the PNS. Composition of neutron star matter. Neutrino processes responsible of cooling. Core-crust transition density => important for pulsar glitches. R NS ? Lattimer & Prakash, ApJ(2001) Kortelainen et al., PRC 2010 Chen et al., PRC 2010 Piekarewicz et al., Trippa et al., PRC2008 Tsang et al., PRL2009 Steiner et al., ApJ2010

Evolution of a Star massive star => He fusion to carbon and oxygen if the star is heavy enough, this can go on to form neon,magnesium, silicon sequence of fusion reactions definitely ends with iron (the most bound nucleus) after all possible fusion reactions are ceased pressure goes down => star cannot withstand gravitational collapse any longer supernova explosion remnant becomes a white dwarf or a neutron star or a black hole. Onion-like structure More in O. Straniero talk 9

Supernova explosions 2D Models of stellar core collapse do not explode (Buras, Rampp, Janka, Kifonidis, PRL 2004). Missing physics, possibly with respect to the EoS. New generation of simulation codes in 3D (Burrows et al., ApJ 2010). Supernovae explode but the mechanism how from implosion => explosion still unsolved. 10

NS observed as rotating pulsars (1967)

Outer crust 56 Fe ions immersed in an electron gas, as in normal metals. Inner crust Neutron gas in chemical equilibrium with electrons and ions. Ions get very neutron rich, until the neutrons drip from nuclei. Nuclear matter from drip point (4x10 11 g/cc) up to about half the saturation density. Outer core Asymmetric nuclear matter above saturation. Mainly composed by neutrons, protons, electrons and muons. Its exact composition depends on the nuclear matter Equation of State (EoS). Inner core The most unknown region. “Exotic matter”. Hyperons. Kaons? Pions? Quarks ? by Dany Page, UNAM Mexico City Four main layers 12

Properties like maximum possible mass (Oppenheimer - Volkoff limit) detailed composition of matter maximum rotational frequencies (non)-radial oscillation frequencies temperature evolution (cooling) depend crucially on the Equation of State of nuclear matter ! 13

EoS from astrophysical observations of NS binaries Several EoS are EXCLUDED ! Compilation by Jim Lattimer 14

EoS from astrophysical observations from isolated NS All current measurements are consistent with radii in the range 8-12 km. Quark matter in the inner core cannot be excluded TOV inversion to get model- independent EoS allowed region for the EoS (Steiner, Lattimer, 2010) F. Ozel, arXiv: Reports on Progress in Physics 15 Alford, Drago et al., Nature 2007

Ab initio Microscopic NN interaction Many-body technique (BHF, DBHF, Variational, Green’s Functions Theory, Quantum Monte Carlo) The construction of the EoS : two possible philosophies No free parameters. SAFE Several free parameters. FAST Phenomenological Effective NN interaction Density functional theory (DFT) Relativistic mean field models Complication of the nuclear many-body problem At short distance the NN interaction is too strong (more in L. Girlanda talk) Divergency problems in many-body calculations. (More in Gianluca talk) 16 M. Baldo, and F. Burgio, Reports on progress in Physics 75 (2012)

The method of energy density functional : mean field with effective interaction The parameters are adjusted to reproduce the empirical saturation point of symmetric nuclear matter. In general one can introduce a more complex structure for the effective forces (gradient terms, etc.) and correspondingly more parameters. In this case it is possible to reproduce also the binding energy and radii of spherical nuclei with a high degree of accuracy and many spectroscopic data (giant resonances, and so on ) 17

Symmetry energy J. R. Stone, “Skyrme Interaction and Nuclear Matter Constraints”, arXiv: Binding energy of SNM and PNM The density dependence of E for SNM is rather similar for all the selected Skyrme forces and compares well with APR model. This doesn’t hold true for PNM, which agrees with the APR result only for SLy6. Skyrme forces

Bethe-Goldstone equation for the G-matrix Two different many-body techniques : BHF vs. Variational Variational method Ansatz : the ground state wave function Ψ can be written as where Φ is the unperturbed ground state wave function and the correlation factor f(r ij ) is determined by the variational principle, i.e. by assuming that the mean value of the Hamiltonian gets a minimum Akmal, Pandharipande & Ravenhall, PRC 58, 1804 (1998) 19

Neutron Matter Symmetric Matter Dependence on the many-body scheme  For the Av18 interaction, good agreement between var. and BBG up to 0.6 fm-3 (symmetric and neutron matter).  The many-body treatment of nuclear matter EOS can be considered well understood. up to density below 0.6 fm -3. At two-body level, both methods give quite similar results. Both methods give the wrong saturation point ! 20

SP Coester et al., Phys. Rev. C1, 769 (1970) Missing the saturation point ……. When three hole-line diagrams are included and modern NN interactions are used the Coester band reduces to a Coester “island” The saturation “point” is still missed. Just like in the early calculations 21

Z.H. Li, U. Lombardo, H.-J. Schulze, W. Zuo, PRC 74, (2006) 22 The problem is common to all non-relativistic many-body methods. Three- body forces have to be included. ① They must allow to reproduce “reasonably well” also the data on three and four nucleon systems. ② They must be consistent with the two-body force adopted. Only partially explored ! New Coester band

Microscopic EoS’s reproduce well the experimental data 23

Symmetry energy crucial for the proton fraction This is the main mechanism of NS cooling which dominates all other processes when the proton fraction is larger than about 12%. 24                           o APR

25 Effects of superfluidity on cooling Cas A Observations of CasA put constraints Superfluidity of neutrons in the 3 P 2 channel Lower limit on the gap Δ≈1 MeV P. Shternin, MNRAS 2011 Superfluidity as open problem in NS physics Baldo et al., PRC 1998 Lombardo & Schulze, Lect.Notes.Phys. 2001

Neutron star Mass M and Radius R APR : variational ABPR : hybrid ( variational + MIT) BBB : Brueckner-Hartree-Fock MS : FT with meson exchange GS : FT with kaon condensate SQM : strange quark matter from F. Ozel, “Surface emission from Neutron Stars and Implications for the Physics of their interiors”, arXiv: Different many-body techniques and matter compositions predict different results for the M-R relation. 26

Iperoni  Few experimental data of hypernuclei on NH interaction. Unknown HH interaction. Nijmegen parametrization, Phys. Rev. C (1989)  Several differences between BHF and RMF in the populations. Σ - do not appear in RMF.  Softening of the EoS in both approaches.  Small limiting masses (below 1.6)  New experimental data from hypernuclei are needed. Large values of the density for the limiting mass ======> transition to quark matter BHF RMF 27

Quark matter in NS (hybrid stars) Several models of quark matter MIT bag model Nambu-Jona—Lasinio model Color Dielectric model Dyson-Schwinger model They all give different hybrid star structure and mass limits. Since we have no theory which describes both confined and deconfined phases, we use two separate EOS for baryon and quark matter and look at the crossing in the P-μ plane. Constraints from nuclear phenomenology on the general quark EOS : In symmetric nuclear matter one can expect a transition to quark matter at some density, but it must be larger than at least normal nuclear matter density. Maximum NS mass at least equal to 1.97 M 0 28

Quark models 29 MIT : hadron + mixed + pure quark phases but adding repulsion => NJL : hadron + mixed phases Kurkela et al. PRD 81, (2010) DSM : hadron + mixed phases

Aaaaah ! 30

LOFT: the Large Observatory For x-ray Timing LOFT Consortium: national representatives: Jan-Willem den HerderSRON, the Netherlands Marco Feroci INAF/IAPS-Rome, Italy Luigi Stella INAF/OAR-Rome, Italy Michiel van der Klis Univ. Amsterdam, the Netherlands Thierry CourvousierISDC, Switzerland Silvia ZaneMSSL, United Kingdom Margarita Hernanz IEEC-CSIC, Spain Søren BrandtDTU, Copenhagen, Denmark Andrea Santangelo Univ. Tuebingen, Germany Didier BarretIRAP, Toulouse, France Renè Hudec CTU, Czech Republic Andrzej Zdziarski N. Copernicus Astron. Center, Poland Juhani HuovelinUniv. of Helsinki, Finland Paul RayNaval Research Lab, USA Joao BragaINPE, Brazil Tad TakahashiISAS, Japan LOFT Science Team composed of scientists from: Australia, Brazil, Canada, CzechRepublic, Denmark, Finland, France, Germany, Greece, Ireland, Israel, Italy, Japan, theNetherlands, Poland, Spain, Sweden, Switzerland, Turkey, United Kingdom, USA