| Lecturers | p. ix |
| Seminar Speakers | p. xi |
| Participants | p. xiii |
| Preface (French) | p. xvii |
| Preface (English) | p. xxi |
| The Birth of Nuclear Physics | p. 1 |
| Discovery of radioactivity, polonium and radium | p. 5 |
| Radiations | p. 8 |
| Radioactive change | p. 9 |
| First applications | p. 11 |
| From the atomic nucleus to the first nuclear reaction | p. 12 |
| [beta]-Decay | p. 14 |
| Nuclear physics | p. 17 |
| Fission | p. 20 |
| References | p. 23 |
| Elementary Features of Nuclear Structure | p. 25 |
| Introduction | p. 29 |
| Chaotic structures in nuclear spectra | p. 29 |
| Independent particle motion | p. 42 |
| Fermi liquids | p. 53 |
| Bose liquids | p. 56 |
| Shell structure | p. 58 |
| Pairing | p. 66 |
| Deformation and rotation | p. 83 |
| Connection of deformation and rotation | p. 92 |
| Competition between pairing and deformation | p. 98 |
| High-spin states and super deformation | p. 105 |
| Super deformation | p. 111 |
| References | p. 120 |
| Nuclear Collective Motion | p. 123 |
| Note to the reader | p. 127 |
| Introduction | p. 127 |
| Theoretical tools | p. 129 |
| The response function | p. 129 |
| Sum rules | p. 131 |
| Mean field theory | p. 133 |
| Skyrme Hamiltonian | p. 134 |
| Gogny Hamiltonian | p. 135 |
| Relativistic mean field | p. 135 |
| Which is best? | p. 136 |
| Time-dependent mean field theory | p. 136 |
| Collective motion | p. 136 |
| Application to giant dipole: Goldhaber-Teller mode | p. 138 |
| RPA response | p. 141 |
| Separable interactions | p. 143 |
| An example: the giant dipole | p. 145 |
| Quadrupole motion | p. 146 |
| Collective motion at low frequencies | p. 148 |
| Surface response in the large A limit | p. 149 |
| Pairing effects | p. 151 |
| Nuclear equation of state | p. 154 |
| Finite excitation energy | p. 157 |
| Compressibility and the monopole resonance | p. 158 |
| Damping of collective motion | p. 161 |
| Landau damping | p. 161 |
| Direct escape | p. 162 |
| Beyond mean field | p. 165 |
| Large amplitude motion | p. 167 |
| Multiple phonons | p. 168 |
| Hot fission | p. 170 |
| References | p. 173 |
| High Spin Experimental Physics | p. 175 |
| Introduction (lecture 1) | p. 179 |
| Formation of rapidly rotating nuclei | p. 179 |
| Gross features of the photon spectra | p. 181 |
| Rotation of deformed nuclei | p. 182 |
| Single particle motion in deformed nuclei | p. 183 |
| Signals from rapidly rotating nuclei | p. 185 |
| Interpretation of the signals | p. 186 |
| Interpretation of spectra | p. 189 |
| Strongly deformed structures | p. 190 |
| Introduction (lecture 2) | p. 193 |
| Analysis of the quasi-continuum | p. 195 |
| The quasi-continuum of superdeformed states | p. 202 |
| Cold Nuclear Rearrangement Processes in Fusion and Fission | p. 207 |
| Introduction | p. 211 |
| Where are we in the production of the heaviest elements? | p. 211 |
| Fission barriers and shell corrections | p. 214 |
| Clusters and temperature | p. 217 |
| Evidences from fusion reactions | p. 217 |
| Evidences from fission | p. 219 |
| Cluster aspects in the fusion entrance channel | p. 222 |
| Theoretical predictions on entrance channel limitations | p. 222 |
| Macroscopic models | p. 222 |
| Microscopic models | p. 224 |
| Evidence of entrance channel limitation from fusion reactions | p. 225 |
| The concept of fusion probability | p. 228 |
| Comparison to experimental data | p. 230 |
| Clusters and compactness | p. 233 |
| The [superscript 208]Pb-cluster - key to SHE production | p. 236 |
| References | p. 240 |
| The Production of Radioactive Nuclear Beams, Present and Future Facilities | p. 243 |
| Introduction | p. 247 |
| General considerations | p. 247 |
| The production of accelerated radioactive nuclear beams | p. 249 |
| In-flight production | p. 250 |
| The production method | p. 250 |
| Existing facilities | p. 252 |
| Proposed facilities | p. 253 |
| ISOL-type facilities | p. 254 |
| Primary beams and production cross sections | p. 254 |
| Ion sources and the production yields of radioactive ions | p. 257 |
| Ion sources | p. 257 |
| Charge amplifiers | p. 259 |
| The post-accelerators | p. 259 |
| Summary and outlook | p. 260 |
| References | p. 262 |
| Phase Transitions in Nuclear Matter and Fragmentation of Finite Nuclei | p. 265 |
| Introduction | p. 269 |
| Phase transitions | p. 270 |
| The liquid-gas phase transition | p. 270 |
| The nuclear caloric curve | p. 272 |
| Clustering as a signature of phase transitions | p. 274 |
| Statistical equilibrium models | p. 275 |
| The lattice-gas model | p. 275 |
| Mapping into the Ising model | p. 276 |
| High-temperature limit | p. 278 |
| Mean field approximation | p. 278 |
| Thermodynamics | p. 281 |
| Clustering | p. 282 |
| Stable droplets | p. 284 |
| The percolation phase transition | p. 286 |
| Critical behavior in nuclear fragmentation | p. 289 |
| Summary | p. 291 |
| References | p. 292 |
| Multifragmentation of Nuclei | p. 295 |
| Introduction | p. 299 |
| Multifragmentation and the nuclear equation of state: spinodal decomposition and the liquid-gas phase transition | p. 300 |
| Multifragmentation and the microscopic transport models: the transport properties of nuclear matter | p. 302 |
| Plan of the lectures | p. 303 |
| Experimental tools | p. 303 |
| Detectors | p. 303 |
| Analysis tools | p. 305 |
| Event generators and simulations | p. 309 |
| Conclusion | p. 310 |
| Reaction mechanisms in the Fermi energy range | p. 311 |
| Data: the dominance of binary processes | p. 311 |
| The role of dynamics | p. 312 |
| Reaction mechanisms: comparison with theory | p. 315 |
| Thermodynamical features of nuclear multifragmentation | p. 315 |
| Rise and fall of multifragment emission | p. 316 |
| Multifragmentation and thermalization: time scale measurements | p. 318 |
| Nuclear thermodynamics: excitation energy and temperature measurements | p. 322 |
| Nuclear calorimetry | p. 323 |
| Nuclear thermometry | p. 326 |
| Multifragmentation and phase transition | p. 330 |
| The caloric curve | p. 330 |
| Critical behaviour of charge distributions | p. 334 |
| Thermal features of multifragmentation: reducibility and thermal scaling | p. 334 |
| Dynamical features of nuclear multifragmentation | p. 338 |
| Expansion and bulk instabilities | p. 339 |
| Coulomb and shape instabilities | p. 342 |
| Conclusion | p. 345 |
| References | p. 347 |
| Signals from Dense Matter | p. 353 |
| Introduction | p. 357 |
| Transport theory | p. 359 |
| Derivation | p. 359 |
| Fermi-energy regime | p. 359 |
| Relativistic energies | p. 362 |
| Coupled channel transport theory | p. 364 |
| Observables | p. 365 |
| Photons | p. 366 |
| Pions and etas | p. 368 |
| Pion production | p. 368 |
| [eta] Production | p. 370 |
| Resonance matter | p. 372 |
| Resonances in dense matter | p. 372 |
| Resonance properties | p. 372 |
| Observable consequences of resonance matter | p. 373 |
| Resonance population | p. 373 |
| Effects on subthreshold particle production | p. 374 |
| Pion annihilation | p. 375 |
| Dilepton radiation | p. 375 |
| Dilepton radiation from heavy-ion collisions | p. 375 |
| Dilepton sources in heavy-ion reactions | p. 375 |
| Pion annihilation | p. 377 |
| Vector mesons in dense matter | p. 378 |
| Vector meson messes in dense nuclear matter | p. 378 |
| Observable consequences | p. 379 |
| Relativistic energies | p. 379 |
| Ultrarelativistic energies | p. 381 |
| Timelike electromagnetic formfactors | p. 382 |
| Vector meson dominance | p. 382 |
| Dilepton radiation from pp collisions | p. 384 |
| Summary | p. 386 |
| References | p. 387 |
| Electromagnetic and Weak Interactions in Nuclei | p. 391 |
| Introduction | p. 395 |
| Describing the ground state of nuclear matter by an "independent particle state" | p. 397 |
| Constructing a quasi-particle and determining some of its electromagnetic properties | p. 399 |
| A schematic model | p. 399 |
| The Coulomb interaction | p. 402 |
| The nucleon in nuclear matter: effects in relation with its meson (pion) cloud | p. 405 |
| [pi]-Exchange force | p. 405 |
| In-medium electromagnetic properties of the nucleon: Pauli effect | p. 407 |
| Using physical or bare nucleons? | p. 409 |
| Energy-dependent NN interaction and electromagnetic observables | p. 410 |
| Energy dependent NN interaction potential | p. 410 |
| Extra electroweak contribution in the impulse approximation | p. 412 |
| Meson in flight contribution (recoil current) | p. 413 |
| Where is the meson content, [characters not reproducible], gone? | p. 415 |
| The swelling of nucleons in nuclei and the Roper resonance | p. 416 |
| Description of a swollen nucleon | p. 416 |
| Charge form factor of the swollen nucleon | p. 418 |
| Conclusion | p. 420 |
| References | p. 421 |
| Quarks, Hadrons and Dense Nuclear Matter | p. 423 |
| Introduction | p. 427 |
| Elements of low energy QCD | p. 428 |
| Symmetries and currents | p. 429 |
| Baryon and flavour currents | p. 430 |
| Massless quarks: chiral symmetry | p. 432 |
| Spontaneous symmetry breaking | p. 433 |
| Realizations of chiral symmetry | p. 433 |
| Goldstone bosons | p. 434 |
| The chiral condensate | p. 434 |
| PCAC and the Gell-Mann, Oakes, Renner relation | p. 435 |
| Running quark mass in the presence of a chiral condensate | p. 436 |
| A schematic model: Nambu and Jona-Lasinio | p. 437 |
| The axial anomaly | p. 441 |
| The meson spectrum | p. 443 |
| Pseudoscalar meson nonet | p. 443 |
| Vector mesons | p. 444 |
| Intermediate summary: vacuum structure and hadron spectrum | p. 448 |
| The QCD vacuum | p. 448 |
| Hadrons and the gap | p. 449 |
| Chiral effective field theory | p. 450 |
| Preparations | p. 450 |
| Chiral effective Lagrangian: meson sector | p. 451 |
| Pion-pion scattering | p. 454 |
| Introducing vector mesons | p. 455 |
| The pion form factor | p. 458 |
| Chiral effective Lagrangian including baryons | p. 460 |
| Basic steps | p. 461 |
| Electromagnetic interactions | p. 463 |
| Next-to-leading order | p. 463 |
| Baryon masses and sigma terms | p. 464 |
| Strange quarks in the nucleon | p. 465 |
| Chiral low energy theorems | p. 466 |
| Goldberger-Treiman relation | p. 466 |
| S-Wave pion-nucleon scattering: Weinberg-Tomozawa theorem | p. 467 |
| Charged pion photoproduction: Kroll-Ruderman theorem | p. 468 |
| Neutral pion photoproduction | p. 468 |
| Baryon resonances | p. 469 |
| Chiral SU (3) dynamics | p. 471 |
| Coupled channels method | p. 472 |
| Low-energy K N interactions and the [Lambda] (1405) | p. 473 |
| Coupled [pi] N, [eta] N and kaon-hyperon system | p. 476 |
| Photoproduction of [eta] mesons | p. 476 |
| Short note: chiral dynamics and the nucleon-nucleon interaction | p. 478 |
| Intermediate summary and comments | p. 480 |
| Hadrons in dense matter | p. 481 |
| Prelude | p. 481 |
| Chiral thermodynamics | p. 482 |
| Hellmann-Feynman theorem | p. 482 |
| Example: free Fermi gas of nucleons | p. 484 |
| Example: thermal pion gas | p. 486 |
| Chiral condensate from lattice QCD | p. 487 |
| Schematic picture: NJL model | p. 488 |
| The chiral condensate in dense nuclear matter | p. 490 |
| Effects of correlations | p. 491 |
| Scalar mean field in nuclei | p. 492 |
| Pions in a nuclear medium | p. 493 |
| Pion mass in matter | p. 494 |
| Deeply bound pionic states | p. 496 |
| Kaons in dense matter | p. 498 |
| Density dependence of kaon masses | p. 501 |
| Subthreshold kaon production in nuclear collisions | p. 502 |
| Kaon condensation | p. 504 |
| Vector mesons in dense matter | p. 504 |
| Current-current correlation function in baryonic matter | p. 506 |
| The rho meson in matter | p. 507 |
| Dilepton production in nuclear collisions | p. 511 |
| References | p. 512 |
| Introduction to QCD | p. 517 |
| Introduction | p. 521 |
| QCD: the Lagrangian and the running coupling | p. 521 |
| Quarks and gluons | p. 521 |
| Quantization | p. 523 |
| The Feynman rules | p. 523 |
| Renormalization | p. 524 |
| The running coupling and the [Lambda]-parameter | p. 526 |
| The parton model | p. 528 |
| e[superscript +] - e[superscript -] [right arrow] hadrons | p. 528 |
| Deep inelastic electron scattering (kinematics) | p. 531 |
| Deep inelastic scattering (parton model) | p. 532 |
| Physical motivation of parton model | p. 535 |
| QCD improved parton model | p. 535 |
| Factorization and the hard scattering picture in QCD | p. 538 |
| Proton(p1) + Proton(p2) [right arrow] [mu superscript +] [mu superscript -](q) + anything | p. 538 |
| Jet production in proton-proton collisions | p. 542 |
| Spin dependence and the axial anomaly | p. 544 |
| Kinematics of spin dependent deep inelastic lepton scattering | p. 544 |
| The operator product expansion and the anomaly | p. 545 |
| Bare quarks and constituent quarks | p. 549 |
| High energy quarks and gluons in hot and cold QCD matter | p. 552 |
| The physical picture and results | p. 552 |
| Multiple scattering in the medium | p. 554 |
| Elementary scattering (hot matter) | p. 555 |
| Elementary scattering (cold matter) | p. 555 |
| Between scatterings | p. 555 |
| The equations | p. 556 |
| Jet broadening | p. 556 |
| Induced radiation spectrum | p. 557 |
| Solutions | p. 560 |
| Jet p[subscript perpendicular, bottom]-broadening | p. 560 |
| Induced gluon spectrum and energy loss | p. 560 |
| Estimates | p. 561 |
| Hot matter | p. 562 |
| Cold matter | p. 562 |
| ([mu]/[lambda])v from the gluon distribution of the nucleon | p. 562 |
| ([mu superscript 2]/[lambda])v from dijet data | p. 563 |
| References | p. 564 |
| Exclusive Reactions in QCD | p. 567 |
| Introduction | p. 571 |
| Space-time picture and counting rules | p. 571 |
| Calculating a hard exclusive amplitude: the example of the pion form factor | p. 573 |
| Description of the pion | p. 574 |
| The hard scattering at the Born level | p. 575 |
| Radiative corrections | p. 578 |
| Transverse degrees of freedom | p. 580 |
| Experimental review | p. 581 |
| Other hard scattering processes | p. 582 |
| The proton distribution amplitude | p. 582 |
| The proton magnetic form factor | p. 583 |
| Compton scattering | p. 584 |
| Virtual Compton Scattering | p. 585 |
| Other processes | p. 585 |
| Color transparency | p. 586 |
| The physical idea | p. 586 |
| An instructive calculation | p. 587 |
| Present data and future prospects | p. 589 |
| References | p. 590 |
| The Quark-Gluon Plasma and Nuclear Collisions at High Energy | p. 593 |
| Introduction | p. 597 |
| Ultrarelativistic matter: from the early universe to nucleus-nucleus collisions at high energy | p. 601 |
| Introduction | p. 601 |
| Brief thermal history of the universe | p. 602 |
| Thermodynamics of relativistic particles | p. 605 |
| Dynamics of the expansion | p. 608 |
| Early universe | p. 608 |
| Nucleus-nucleus collision at high energy | p. 612 |
| Particle masses and symmetry breaking | p. 614 |
| Three approaches to the quark-hadron transition | p. 617 |
| The hadron gas and the Hagedorn temperature | p. 618 |
| The quark-hadron transition in the bag model | p. 620 |
| Chiral dynamics | p. 628 |
| Chiral symmetry, chiral condensate, Goldstone bosons | p. 628 |
| A simple lagrangian for the Goldstone bosons | p. 630 |
| First principle calculations | p. 634 |
| Finite temperature calculations | p. 634 |
| High order calculations of the free energy | p. 637 |
| Lattice gauge calculations | p. 639 |
| The deconfinement transition in pure gauge theory | p. 646 |
| The value of the critical temperature | p. 647 |
| The equation of state | p. 647 |
| Potential between heavy quarks | p. 648 |
| Chiral transition | p. 649 |
| Collective excitations of the quark-gluon plasma | p. 649 |
| Introduction | p. 649 |
| Non-relativistic and ultrarelativistic ideal plasmas | p. 651 |
| Non-relativistic plasmas | p. 651 |
| Ultrarelativistic plasmas | p. 653 |
| A hierarchy of scales in ultra-relativistic plasmas | p. 654 |
| Non-abelian plasmas | p. 655 |
| Screening, Landau damping, collective modes | p. 656 |
| Screening | p. 656 |
| Landau damping | p. 658 |
| Collective modes | p. 659 |
| Lifetime of excitations | p. 664 |
| Quasiparticles | p. 664 |
| Infrared problems | p. 664 |
| Non exponential damping | p. 666 |
| Nucleus-nucleus collisions at high energy | p. 667 |
| Some kinematics. Rapidity distributions | p. 668 |
| Center of mass versus laboratory frames | p. 668 |
| Rapidity | p. 669 |
| Rapidity interval | p. 671 |
| Rapidity distributions. Central and fragmentation regions | p. 671 |
| The experimental program | p. 672 |
| Relativistic hydrodynamics | p. 673 |
| Equations of hydrodynamics for relativistic fluids | p. 674 |
| Landau and Bjorken initial conditions | p. 676 |
| Longitudinal expansion in scaling hydrodynamics | p. 679 |
| Collision geometry and transverse energy | p. 680 |
| Hadronic observables | p. 684 |
| Effects of a phase transition on global observables | p. 685 |
| Hadron interferometry | p. 689 |
| Strangeness production | p. 696 |
| Hints of thermalisation | p. 696 |
| Disoriented chiral condensates | p. 697 |
| The J / [Psi] meson in nuclear collisions | p. 698 |
| The J / [Psi] meson | p. 699 |
| Models of J / [Psi] production in hadronic collisions | p. 699 |
| The J / [Psi] in a quark-gluon plasma | p. 701 |
| Screening and disappearance of bound states | p. 701 |
| A simple model for J / [Psi] suppression in an expanding plasma | p. 702 |
| J / [Psi] production in hadron-hadron and hadron-nucleus collisions | p. 705 |
| Medium effects. Nuclear absorption | p. 705 |
| Nucleus-nucleus collisions | p. 706 |
| Nuclear absorption | p. 706 |
| Initial state scattering and the P[subscript T] distribution | p. 708 |
| Comovers | p. 709 |
| The recent Pb-Pb data: a surprise! | p. 711 |
| References | p. 713 |
| Neutron Stars and Nuclear Physics | p. 717 |
| Introduction and history | p. 721 |
| Observational aspects | p. 724 |
| Overview of matter at high densities | p. 726 |
| Nuclei in the outer crust | p. 729 |
| Neutron drip | p. 731 |
| Nuclei in the inner crust | p. 734 |
| Non-spherical nuclei | p. 734 |
| Neutron skins and elemental abundances | p. 736 |
| The neutron skin | p. 736 |
| The rapid neutron capture process | p. 738 |
| Effective interactions for nucleons | p. 740 |
| Neutron drops | p. 740 |
| Matter in neutron star cores | p. 741 |
| Concluding remarks | p. 748 |
| References | p. 748 |
| Hybrid Systems for Waste Incineration and Energy Production | p. 751 |
| Introduction | p. 755 |
| Breeding and transmutation | p. 756 |
| Breeding | p. 756 |
| Transmutation and incineration | p. 757 |
| Official reprocessing policy | p. 758 |
| Alternative policies | p. 759 |
| The Thorium-Uranium cycle | p. 760 |
| Principle of hybrid systems | p. 760 |
| Accelerators and spallation reactions | p. 760 |
| Neutrons multiplying assemblies | p. 761 |
| Neutron balance | p. 762 |
| Fuel evolution | p. 764 |
| Liquid fuel systems | p. 766 |
| Solid fuels | p. 767 |
| Strategical evaluation of hybrid systems | p. 768 |
| Transmute nuclei | p. 768 |
| Energy production | p. 770 |
| The proposal of C.D. Bowman | p. 770 |
| The proposal of C. Rubbia | p. 771 |
| The safety features | p. 773 |
| Sub-criticality | p. 773 |
| Natural convection | p. 776 |
| Passive safety | p. 776 |
| Sociological safety | p. 777 |
| Neutronic | p. 777 |
| Incineration of transuranic elements | p. 777 |
| Cost estimates | p. 778 |
| Conclusion | p. 780 |
| References | p. 781 |
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