Verfügbarkeit: Nuclear fusion

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1. Verfasser:	Morse, Edward (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Cham, Switzerland Springer [2019]
Ausgabe:	Corrected publication
Schriftenreihe:	Graduate texts in physics
Schlagworte:	Nuclear Energy Nuclear Fusion Plasma Physics Nuclear Engineering Nuclear Physics, Heavy Ions, Hadrons Nuclear fusion Nuclear engineering Nuclear physics Kernfusion
Online-Zugang:	Inhaltsverzeichnis Klappentext
Beschreibung:	xxii, 512 Seiten Illustrationen, Diagramme
ISBN:	9783319981703

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Datensatz im Suchindex

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adam_text	Contents 1 Fundamental Concepts ............................................................................... 1.1 The Promise of Fusion Energy......................................................... 1.2 History of Fusion Research............................................................... 1.2.1 Magnetic Confinement Experiments............................... 1.2.2 Inertial Confinement Fusion (ICF).................................. 1.3 Some Final Comments....................................................................... References....................................................................................................... 1 1 3 4 14 19 19 2 Fusion Nuclear Reactions........................................................................... 2.1 Cross Sections and Reactivity........................................................... 2.2 Solar Fusion Reactions....................................................................... 2.3 Fusion Reactions for Terrestrial Energy Production....................... 2.3.1 Catalyzed D-D.................................................................... References....................................................................................................... 23 23 24 28 35 36 3 Collisions and Basic Plasma Physics......................................................... 3.1 Plasma Properties............................................................................... 3.1.1 Plasma Oscillations........................................................... 3.1.2 Debye Screening............................................................... 3.2 Coulomb Collisions........................................................................... 3.2.1 Coulomb Kinematics......................................................... 3.2.2 Momentum and Energy Loss for a Test Particle............ 3.2.3 Energy and Momentum Loss in a Maxwellian Plasma.. 3.2.4 Beam-Plasma Fusion with Slowing Down...................... 3.2.5 Runaway Electrons............................................................ 3.3 Collisions in Velocity Space............................;................................ 3.4 Dynamics of Particles in Magnetic Fields ....................................... 3.4.1 Cyclotron Motion.............................................................. 3.4.2 E x В Drift......................................................................... 3.4.3 Changing Magnetic Field: μ Conservation.................... 39 39 39 42 44 44 49 50 53 55 58 61 61 62 63 ix x Contents 3.4.4 Grad-B Drift................................................................... 3.4.5 Curvature Drift............................................................... 3.4.6 The Magnetic Mirror Effect........................................... 3.4.7 Polarization Drift............................................................ 3.4.8 Magnetization Current................................................... 3.4.9 The Plasma Current........................................................ Problems ................................................................................................... References.................................................................................................. 66 66 67 70 71 71 72 73 4 Energy Gain and Loss Mechanisms in Plasmas and Reactors.......... 4.1 Bremsstrahlung............................................................................... 4.2 Line and Recombination Radiation................................................ 4.2.1 Basic Concepts ............................................................. 4.2.2 Radiation in Optically Thin Plasmas............................. 4.2.3 Radiation in Optically Thick Plasmas............................ 4.3 Charge Exchange............................................................................ 4.4 Synchrotron Radiation................................................................... 4.5 Energy Balance and the Lawson Criterion..................................... 4.5.1 Advanced Energy Recovery Cycles............................... 4.5.2 The Lawson Concept Applied to Inertial Fusion.......... Problems................................................................................................... References................................................................................................. 75 75 80 80 82 90 94 96 97 100 104 106 107 5 Magnetic Confinement........................................................................... 5.1 Fluid Equations for Plasma: MHD Model...................................... 5.1.1 The MHD Limit............................................................. 5.2 MHD Equilibria.............................. 5.2.1 General Stationary Equilibria......................................... 5.2.2 Static Equilibria............................................................. 5.2.3 A Simple Slab MHD Equilibrium Model...................... 5.2.4 Thez-Pinch.................................................................... 5.3 Confinement in Axisymmetric Systems......................................... 5.3.1 Toroidal and Poloidal Fields........................................... 5.3.2 Solov’ev Equilibria......................................................... 5.3.3 Solution with Whittaker Functions................................ 5.3.4 The Safety Factor q....................................................... Problems.................................................................................................. References................................... 109 109 Ш 113 113 113 115 117 118 118 120 121 126 131 132 6 Magnetohydrodynamic Stability............................................................ 6.1 Fluid Perturbations in Plasma....................................................... 6.1.1 Linearized Perturbations to Stationary («o = 0) Equilibrium.................................................................... 6.1.2 Special Solutions to the Ideal MHD Equation............... 6.2 MHD Energy Principle................................................................... 6.2.1 The Intuitive Form of S W................................................. 133 133 133 136 137 139 Contents xi 6.3 MHD Stability of Tokamaks ............................................................ 6.3.1 Internal Kink Mode........................................................... 6.4 Resistive MHD................................................................................... 6.4.1 Magnetic Reconnection..................................................... 6.4.2 The Resistive Tearing Mode (m փ 1)............................. 6.4.3 Magnetic Islands............................................................... 6.4.4 Resistive MHD for m = ո — 1 Mode............................. 6.4.5 Disruptions........................................................................ 6.4.6 Hugill Diagram.................................................................. 6.4.7 Mode Locking.................................................................... 6.4.8 Magnetic Stochasticky...................................................... 6.5 Neoclassical Tearing Modes.............................................................. 6.6 Edge Localized Modes (ELMs)........................................................ Problems......................................................................................................... References....................................................................................................... 141 143 146 146 150 155 157 160 160 162 165 168 170 173 175 7 Transport....................................................................................................... 7.1 Moments of the Fokker-Planck Equation........................................ 7.2 Braginskii Transport Coefficients.................................................... 7.3 Gyro-Kinetic Transport..................................................................... 7.4 Neoclassical Transport....................................................................... 7.4.1 Orbits and Collisionality................................................... 7.4.2 Pfirsch-Schffiter Transport................................................ 7.4.3 Plateau Transport............................................................... 7.4.4 Banana Regime.................................................................. 7.5 Turbulence and Transport.................................................................. 7.6 Empirical Scaling Laws..................................................................... Problems......................................................................................................... References....................................................................................................... 177 177 181 190 192 194 197 199 202 206 209 211 212 8 Stellarators.................................................................................................... 8.1 Introduction and History........................... 8.2 MHD Equilibrium.............................................................................. 8.3 Stability............................................................................................... 8.4 Transport.............................................................................................. 8.4.1 Collisionless Transport, Omnigeneity, and Quasi-Symmetry............................................................... 8.4.2 Neoclassical Transport...................................................... 8.5 Density Limit, Anomalous Transport, and Scaling Laws.............. 8.5.1 Density Limit..................................................................... 8.5.2 Anomalous Transport....................................................... 8.5.3 Scaling Laws..................................................................... Problems......................................................................................................... References....................................................................................................... 215 215 219 221 225 225 227 231 231 232 232 233 233 xii 9 10 Contents Plasma Heating in Magnetic Fusion Devices.......................................... 9.1 Introduction and History.................................................................... 9.1.1 Survey of Heating Methods.............................................. 9.2 Neutral Beam Injection..................................................................... 9.2.1 Neutralization.................................................................... 9.2.2 Penetration into Plasma.................................................... 9.2.3 Accelerator Physics........................................................... 9.2.4 ITER Design..................................................................... 9.3 Radiofrequency Wave Heating ......................................................... 9.3.1 Introduction and History................................................... 9.3.2 RF Heating Basics: Propagation and Absorption of RF Energy in Plasma.................................................... 9.3.3 Cutoffs and Resonances.................................................... 9.3.4 Wave-Normal Surfaces...................................................... 9.3.5 Accessibility and the CMA Diagram............................... 9.3.6 Ray Tracing........................................................................ 9.3.7 Bernstein Waves................................................................. 9.3.8 Mode Conversion and Tunneling..................................... 9.3.9 RF Heating: Resonant Frequencies in Plasma............... Problems ........................................................................................................ References....................................................................................................... Inertial Fusion.............................................................................................. 10.1 Introduction and History.................................................................... 10.1.1 Differences Between Nuclear Explosive-Driven and Laboratory Fusion Experiments............................... 10.2 Direct vs. Indirect Drive.................................................................... 10.3 Interaction of Laser Light with Matter............................................. 10.3.1 Inverse Bremsstrahlung.................................................... 10.3.2 Resonance Absorption...................................................... 10.3.3 Nonlinear Effects: Motion of Electrons in High-Amplitude Electromagnetic Fields......................... 10.3.4 Nonlinear Wave Interaction and Parametric Instability....................................................... 10.3.5 Model Equations for Three-Wave Parametric Instability........................................................................... 10.3.6 The Stokes Diagram.......................................................... 10.3.7 Stimulated Raman Scattering (SRS)............................... 10.3.8 Stimulated Brillouin Scattering (SBS)............................ 10.3.9 Two-Plasmon Decay......................................................... 10.3.10 Intra-Beam Transfer............................................................ 10.4 Implosion Hydrodynamics................................................................ 10.4.1 Hydrodynamic Efficiency: The Rocket Equation........... 10.5 Hydrodynamic Instabilities............................................................... 10.5.1 Rayleigh-Taylor Instability.............................................. 10.5.2 Kelvin-Helmholtz Instability........................................... 237 237 237 239 240 246 249 251 256 256 259 263 268 270 272 274 288 291 335 337 345 345 345 347 350 352 353 356 358 360 361 362 364 364 365 366 366 367 368 369 Contents xiii 10.5.3 Richtmeyer-Meshkov Instability................................... 10.5.4 Hydrodynamic Mix....................................................... 10.5.5 Shocks........................................................................... 10.6 Equation of State and Shock Timing............................................. 10.6.1 Fermi Degeneracy.......................................................... 10.6.2 Ion Equations of State: Solid Phase.............................. 10.6.3 Ion Equation Of State: Fluid Phase................................ 10.6.4 Metallic Hydrogen......................................................... 10.6.5 Dissociation of Hydrogen Dimers................................. 10.6.6 Ionization and Plasma EOS............................................ 10.6.7 Hugoniots from Equation of State................................. 10.6.8 Shock Timing................................................................. 10.6.9 Ignition Strategy for NIF................................................ 10.7 Laser Technology .......................................................................... 10.7.1 Frequency Doubling and Tripling................................. 10.7.2 Deformable Mirrors....................................................... 10.7.3 Plasma Electrode Pockels Cells.................................... 10.8 Advanced Driver Concepts........................................................... 10.8.1 KrF Lasers..................................................................... 10.8.2 Diode-Pumped Solid State Lasers................................. 10.8.3 Heavy Ion Accelerator Drivers...................................... Problems .................................................................................................. References..................... 371 374 375 379 379 387 390 393 393 394 395 396 397 399 399 400 401 403 403 404 404 405 407 11 Fusion Technology................................................................................... 11.1 Materials Issues in Magnetic Fusion Reactors.............................. 11.1.1 Sources of Stress........................................................... 11.1.2 Fatigue........................................................................... 11.1.3 Fracture Toughness........................................................ 11.1.4 Radiation Damage: History and Theory ....................... 11.1.5 Helium Production.......................................................... 11.1.6 Material Degradation Due to Radiation Damage.......... 11.1.7 Embrittlement................................................................ 11.1.8 Void Swelling................................................................. 11.1.9 Irradiation Creep........................................................... 11.1.10 Advanced Materials Concepts....................................... 11.1.11 Advanced Steels for Fusion Applications...................... 11.2 Plasma-Surface Interaction........................................................... 11.2.1 Tungsten Surface Modifications Under Ion Exposure... 11.3 Tritium Management...................................................................... 11.3.1 Sievert’s Law and Tritium Permeation.......................... 11.3.2 Solubility and Diffusivity Data....................................... 11.4 Magnets.......................................................................................... 11.4.1 Superconductivity........................................................... 413 413 413 417 418 421 428 429 430 432 434 437 438 439 440 441 443 445 448 449 xiv 12 Contents 11.4.2 Cryogenic Stability......................................................... 11.4.3 Magnet Stresses............................................................. 11.4.4 Electrical Protection....................................................... 11.5 Vacuum Systems............................................................................ 11.5.1 Viscous and Molecular Flow......................................... 11.5.2 ITER Vacuum System.................................................... 11.6 Blanket and Shield Design............................................................. 11.6.1 Introduction.................................................................... 11.6.2 Design for a DT-Buming Large Tokamak Reactor: ARIES-RS....................................................... 11.6.3 A Simple Non-breeding Blanket Design....................... Problems ................................................................................................... References................................................................................................. 453 456 457 458 459 465 468 468 Economics, Environmental, and Safety Issues .................................... 12.1 Introduction.................................................................................... 12.2 Economics and the Cost of Money................................................ 12.2.1 Government Funding...................................................... 12.2.2 Corporate Balance Sheet Financing.............................. 12.2.3 The Exeltium Model...................................................... 12.2.4 The Mankala Model........................................................ 12.2.5 Vendor Equity................................................................ 12.2.6 Export Credit Agencies (ECA) Debt and Financing...... 12.2.7 Private Financing with Government Support Mechanisms................................................................... 12.2.8 Some Concluding Remarks on Economic Competitiveness............................................................. 12.3 Environmental Impact.................................................................... 12.3.1 Licensing Process.......................................................... 12.3.2 Environmental Effects: Tritium...................................... 12.3.3 Onsite Plume Model: DOE Facilities............................ 12.3.4 Environmental Effects of Activated Structural Materials........................................................................ 12.4 Safety Considerations.................................................................... Problems .................................................................................................. References................................................................................................. 481 481 481 482 483 486 486 487 487 Correction to: Nuclear Fusion....................................................................... 469 471 472 473 488 488 489 489 490 492 494 496 498 499 Cl Glossary........................................................................................................... 501 Index 507 Graduate Texts in Physics Edward Morse Nuclear Fusion I he pursuit of nuclear fusion as an energy source requires a broad knowledge of several disciplines. Ihese include plasma physics, atomic physics, electromagnetics, materials science, computational modeling, superconducting magnet technology, accelerators, lasers, and health physics. Nuclear fusion distills and combines these disparate subjects to create a concise and coherent foundation to both fusion science and technology. It examines all aspects of physics and technology underlying the major magnetic and in ertial confinement approaches to developing nuclear fusion energy. It further chronicles latest developments in the field, and reflects the multi faceted nature of fusion research, preparing advanced undergraduate and graduate students in physics and engineering to launch into successful and diverse fusion related research. Nuclear huhu reflects I )r. Morse’s research In both magnetic and inertial confinement fusion, working with the worlds top laboratories, and embodies his extensive thirty five year career in teaching three courses in fusion plasma physics and fusion technology at University of California, berkeley. • ( Combines theory, experiments, and technology into a single teaching text and reference • Written in a concise style, accessible to both physicists and engineers • Presents computation on an equal footing with analytic theory • Hmphasizes the underlying basic science for all of the material presented Dr. Edward Morse is Professor of Nuclear Hnginecring at the University of California, berkeley. I le has authored over 140 publications in the areas of plasma physics, math ematics, fusion technology, lasers, microwave sources, neutron imaging, plasma diag nostics, and homeland security applications, for several years he operated the largest f usion neutron source in the US. Frequently consulted by the media to explain the un derlying science and technology of nuclear energy policy and events, I )r. Morse is also a consultant and expert witness in applications of fusion neutrons to oil exploration. Engineering ISBN 978-3-319-98170-3 9783319981703 ► springer.com
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spelling	Morse, Edward Verfasser (DE-588)1173838015 aut Nuclear fusion Edward Morse Corrected publication Cham, Switzerland Springer [2019] xxii, 512 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Graduate texts in physics Nuclear Energy Nuclear Fusion Plasma Physics Nuclear Engineering Nuclear Physics, Heavy Ions, Hadrons Nuclear fusion Nuclear engineering Nuclear physics Kernfusion (DE-588)4030323-8 gnd rswk-swf Kernfusion (DE-588)4030323-8 s DE-604 Erscheint auch als Online-Ausgabe 978-3-319-98171-0 Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=031321863&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=031321863&sequence=000003&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext
spellingShingle	Morse, Edward Nuclear fusion Nuclear Energy Nuclear Fusion Plasma Physics Nuclear Engineering Nuclear Physics, Heavy Ions, Hadrons Nuclear fusion Nuclear engineering Nuclear physics Kernfusion (DE-588)4030323-8 gnd
subject_GND	(DE-588)4030323-8
title	Nuclear fusion
title_auth	Nuclear fusion
title_exact_search	Nuclear fusion
title_full	Nuclear fusion Edward Morse
title_fullStr	Nuclear fusion Edward Morse
title_full_unstemmed	Nuclear fusion Edward Morse
title_short	Nuclear fusion
title_sort	nuclear fusion
topic	Nuclear Energy Nuclear Fusion Plasma Physics Nuclear Engineering Nuclear Physics, Heavy Ions, Hadrons Nuclear fusion Nuclear engineering Nuclear physics Kernfusion (DE-588)4030323-8 gnd
topic_facet	Nuclear Energy Nuclear Fusion Plasma Physics Nuclear Engineering Nuclear Physics, Heavy Ions, Hadrons Nuclear fusion Nuclear engineering Nuclear physics Kernfusion
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