Laser-Plasma Interactions 4

INTRODUCTION TO THE PHYSICS AND APPLICATIONS OF LASER PRODUCED PLASMAS -- M H KEY -- INTRODUCTION -- 1. LASER FUSION -- Direct drive -- Indirect drive -- Comparison of inertial fusion and magnetic fusion Future facilities -- 2. DENSE PLASMAS -- 3. HIGH INTENSITY LASER PLASMA INTERACTIONS -- 4. PARTICLE ACCELERATORS Wake field acceleration -- 5. XUV AND X-RAY SOURCES AND THEIR APPLICATIONS -- 6. XUV AND X-RAY LASERS -- 7. PARTICLE SOURCES -- 8. DEVELOPMENTS IN LASER TECHNOLOGY -- REFERENCES -- LASER LIGHT PROPAGATION AND INTERACTION WITH PLASMA -- P. MULSER -- 1. CAPACITOR MODEL OF RESONANCE ABSORPTION -- 1.1 Linear resonance absorption -- 1.2 High amplitude electron waves and wavebreaking -- 2. ABSORPTION OF INTENSE fs LASER PULSES -- 2.1 Plasma parameters and the problem of absorption -- 2.2 Collision frequency under strong drift conditions -- Excitation of plasma oscillations by a single fast particle -- Collision frequencies -- Screening and statistical independence -- 2.3 Anomalous skin effect -- 2.4 Ionisation dephasing -- 3. WAVE ACTION AND PROPAGATION IN MODULATED PLASMAS -- 3.1 Generalized ponderomotive action on single particles -- 3.2 Light propagation in periodically modulated plasmas REFERENCES -- LASER—INDUCED RADIATION HYDRODYNAMICS: AN INTRODUCTION -- R. SIGEL -- 1. INTRODUCTION -- 2. RADIATIVE TRANSPORT -- 2.1 Radiation confinement -- 2.2 The hydrodynamic equations -- 2.3 The transport'of energy by radiation 2.4 The maximum opacity theorem -- 3. SELF-SIMILAR SOLUTIONS -- 3.1 The Buckingham theorem and self-similarity -- 3.2 The isothermal rarefaction wave as an example of self-similar gas motion -- 3.3 The radiation driven ablative heat wave -- 4. EXPERIMENTS REFERENCES -- LASER— DRIVEN INSTABILITIES IN LONG SCALELENGTH PLASMAS — II -- W L KRUER -- 1. INTRODUCTION -- 2. STIMULATED RAMAN SCATTERING -- 3. EFFECT OF ION FLUCTUATIONS ON SRS -- 4. LASER BEAM FILAMENTATION -- 5. LASER BEAM SMOOTHING -- 6. SUMMARY REFERENCES -- SPECTROSCOPY AND ATOMIC PHYSI