430 likes | 643 Views
Equation of State for nuclear matter: research at CHARMS. PART I: Generalities about the Equation of State (EOS) for ordinary matter and for nuclear matter. PART II: Our research with the FRS connected to EOS. PART I: Equation of State for ordinary matter and for nuclear matter.
E N D
Equation of State for nuclear matter: research at CHARMS PART I: Generalities about the Equation of State (EOS) for ordinary matter and for nuclear matter PART II: Our research with the FRS connected to EOS
PART I: Equation of State for ordinary matter and for nuclear matter Fundamental interactions and residual forces ATOM MOLECULE LIQUID ordinary matter e.m. interaction residual e.m. interaction (e.g. covalent bond) residual e.m. interaction (molecular force) NUCLEON NUCLEUS nuclear matter strong interaction residual strong interaction (nucleon-nucleon force)
u u r r Range dependence of the residual force molecule-molecule (Lennard-Jones) nucleon-nucleon (Skyrme) Nuclear matter in normal condition (nuclei) behaves as a liquid! The scales are very different: Ordinary matter Nuclear matter Density: 1 g/cm3 3 1014 g/cm3 Typical distance: 10-10 m 10-15 m How do microscopic properties translate into macroscopic properties?
EOS for the ordinary matter How does molecular force change when we have a great number of molecules? How strong is the molecular bond? Macroscopic quantities that are observable when I heat a liquid: - volume, V - pressure, P - temperature, T Relation among V, P, T: theequation of state IDEAL GAS: . REAL GAS (Van der Waals): . strenght intramolecular force volume molecule
Solution of the EOS (van der Waals) for a given material (a and b given) P Isothermes liquid gas high T spinodal region coexistence low T V r measuring P, V, Ta and b intramolecular force 2nd virial coefficient
How can I explore experimentally the P,V diagram? 1) I increase T at constant pressure P Isothermes liquid gas 1 atm 100°C coexistence V r liquid-gas coexistence P constant V increasing T Caloric curve (liquid-gas phase transition) E
heat bath compressibility How can I explore experimentally the P,V diagram? 2) I increase P at constant temperature increase r (compression) P Isothermes liquid gas coexistence V r EOS
Study of the EOS for the nuclear matter “Exploring the nuclear-matter phase-diagram and identifying the different phases of nuclear matter is one of the main challenges of modern nuclear physics.” NUPECC How can I explore experimentally the P,V diagram? • Measuring the phase transitions • Measuring the compressibility Nucleus-nucleus collisions at relativistic energies projectile spectator participant „fireball“ target spectator 2) this part is compressed 1) these parts get excitation energy E*
Liquid-gas phase transition Liquid phase Fragmentation Transition (coexistence) Multifragmentation Vaporisation Gas phase
Phase transition superfluid liquid A25 T/MeV gas 5 coexistence liquid 0.5 superfluid Superfluid phase revealed by structural effects e.g. even-odd staggering E/MeV 10 70 300
Liquid-gas phase transition • What is T? How to measure T? • What is E*? How to measure E*? • What is P? Is it constant? • What is V? Is it measurable?
Classical Temperature Temperature is a macroscopic observable that rules the exchange of energy between bodies. Correlation between the temperature and the energy of the molecules of the ideal gas AT EQUILIBRIUM < x > = < y > = < z > = 1/2 k T T high T low
Nuclear Temperature: zero temperature The nucleus is: a mesoscopic system a fermionic quantum system the nucleons inside the nucleus do not have the same degrees of freedom: they have increasing energy
Nuclear Temperature: non-zero temperature ETOT = a T2 aA E/A T2
Thermometers SLOPE THERMOMETER: Energy spectrum for nucleons from evaporation ISOMER THERMOMETER: Nuclei in a heat bath at T>0. The energy of different isomers will be different ISOTOPE THERMOMETER: Nuclei in a heat bath at T>0. The mass (or binding energy) of different isomers will be different
Excitation energy Excitation energy : quantity related to the individual energy of the nucleons Pressure and Volume Pressure : pressure done by the nucleons Volume: volume occupied by the nucleons ?????
P Isothermes liquid gas 1 atm 100°C coexistence V r Problems behind the liquid-gas phase transition • Costant pressure? Operational definition of the volume? • Quantum system • Mesoscopic system • Fast heating (no thermalisation – no equilibrium) • Mixture of two liquids (proton and neutron subsystems) „Isospin dependence of the EOS“
Compressibility of nuclear matter u Nuclear compressibility is directly related to the nuclear force r (E/A) = Internal energy per nucleon = internal energy stored in compression /0 = normalised density = nuclear compression modulus = curvature at =0 large = hard EOS small = soft EOS
Methods to investigate the compressibility • From fireball (Flow, Kaon production) • From scattering (Giant resonance) Flow The „squeeze out“ or „flow“ is directly related to the gradiente pressure in the fireball nuclear compression modulus Kaon production The bulk of K+ mesons is produced in secondary or multiple reactions of nucleons in the fireball: N1+N2 N1N2 N3 K+ + Such secondary reactions occur predominantly at high nuclear density kaon production yields are sensitive to the compression nuclear compression modulus
Giant monopole resonance The isoscalar giant monopole resonance (GMR) is a compressional mode of excitation. It is of particular interest because its energy is directly related to compressibility. By measuring the inelastically scattered alpha particles at forward angles, including 0° degrees, one can deduce the energy. Problems behind the compressibility • Short time span (dynamical picture hydrodynamical models) • Momentum dependence interaction (MDI) • Mesoscopic system (finite size) • In-medium effects • Mixture of two liquids (proton and neutron subsystems) „Isospin dependence of the EOS“
KAOS The kaon spectrometer is capable of determining the momentum and charge of the particles, their emission angle, the centrality of the reaction including the total number of participating nucleons, and the orientation of the reaction plane. The momentum is measured via the deflection angle of the particle in the magnetic field and its recorded hit position in the focal plane. The velocity is deduced by reconstructing the flight path and measuring the time of flight. With these quantities known, the rest mass and thus the particle species can be unambiguously determined.
FOPI The charged particles produced by a nickel-nickel collision at an energy of 1.93 GeV per nucleon leave tracks in the central drift chamber. The individual signals in the detector (squares) are automatically connected to form the track. Unambiguous identification of the particle is possible from the curvature of the track and additional information from other sections of the FOPI detector. In the example shown, two strange particles (K0 and ) arise simultaneously and decay after a short flight.
PART II: Our research with the FRS connected to EOS 4 detectors „landscape“ FRS „a microscope“ ... a different approach! velocity is calculated from B: veryprecise evaluation
Our observables: velocity spectra and cross sections Z=26 1 A GeV 238U on H2+Ti The integral of these spectra gives us the fission cross-section and the fragmentation cross-section longitudinal velocity
Our observables Fission
Phases A25 T/MeV 4 - gas 5 3 - coexistence 2 - liquid 0.5 1 - superfluid E/MeV 10 70 300
1 - Superfluid phase Fissioning nucleus: 226Th Results from e.m.-induced fission of 70 different secondary projectiles (Steinhäuser et al., Nuc. Phys.A 634 (1998) 89 ) Structural properties survive at low energy Z Structural effects are restored in the end products of hot decaying nuclei
2 - Liquid phase: an example: 1 GeV p on 238U proton 1 GeV fission fragments Intra-nuclear Cascade Sequential Evaporation / Fission
2 - Liquid phase: the cross sections of spallation and fragmentation residues IDEA BEHIND LIMITING FRAGMENTATION "evaporation corridor" or "attractor line"
2 - Liquid phase: the velocity of spallation and fragmentation residues • Morryssey systematics is found to be valid: • for small A in spallation / fragmentation reactions • for compound nuclei which fission
3 - Liquid-gas coexistence: an example: 238U + Pb sequential evaporation 238U fission Pb break-up pre-fragment 238U sequential evaporation Pb
3 - Liquid-gas coexistence: indications in the cross sections of "light" residues
3 - ISOSPIN THERMOMETER break-up abrasion 238U 1.59 evaporation
3 - Liquid-gas coexistence : indications in the cross sections of "light" residues
Liquid-gas coexistence: indications in the velocity of "light" residues
Liquid-gas coexistence : indications in the velocity of "light" residues this is due to a dynamical process! break-up
ABRABLA sequential evaporation 238U fission Pb break-up 238U break-up pre-fragment sequential evaporation Pb
ALADIN data event Z1 Z2 Z3 Z4 Z5 Z6 Z7 Z8 Z9 Z10 Z11 Z12 Zbound Zb3 1 41 20 6 4 3 2 2 0 0 0 0 0 78 74 2 33 21 7 3 2 2 2 0 0 0 0 0 70 64 3 8 4 3 3 3 3 2 2 2 2 0 0 32 24 4 32 13 12 4 2 2 2 2 2 0 0 0 71 61 5 64 4 2 2 0 0 0 0 0 0 0 0 72 68 6 17 12 7 4 3 2 2 2 2 0 0 0 51 43 7 26 10 6 6 3 2 2 2 2 0 0 0 59 51