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Iter Physics [Kõva köide]

(Aix Marseille Univ, France), (Univ Of Texas At Austin, Usa)
  • Formaat: Hardback, 248 pages
  • Ilmumisaeg: 11-Aug-2015
  • Kirjastus: World Scientific Publishing Co Pte Ltd
  • ISBN-10: 981467866X
  • ISBN-13: 9789814678667
Teised raamatud teemal:
Iter PhysicsSuurem pilt
  • Formaat: Hardback, 248 pages
  • Ilmumisaeg: 11-Aug-2015
  • Kirjastus: World Scientific Publishing Co Pte Ltd
  • ISBN-10: 981467866X
  • ISBN-13: 9789814678667
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9789814678667.html
Märksõnad:
The promise of a vast and clean source of thermal power drove physics research for over fifty years and has finally come to collimation with the international consortium led by the European Union and Japan, with an agreement from seven countries to build a definitive test of fusion power in ITER. It happened because scientists since the Manhattan project have envisioned controlled nuclear fusion in obtaining energy with no carbon dioxide emissions and no toxic nuclear waste products.This large toroidal magnetic confinement ITER machine is described from confinement process to advanced physics of plasma-wall interactions, where pulses erupt from core plasma blistering the machine walls. Emissions from the walls reduce the core temperature which must remain ten times hotter than the 15 million degree core solar temperature to maintain ITER fusion power. The huge temperature gradient from core to wall that drives intense plasma turbulence is described in detail.Also explained are the methods designed to limit the growth of small magnetic islands, the growth of edge localized plasma plumes and the solid state physics limits of the stainless steel walls of the confinement vessel from the burning plasma. Designs of the wall coatings and the special "exhaust pipe" for spent hot plasma are provided in two chapters. And the issues associated with high-energy neutrons — about 10 times higher than in fission reactions — and how they are managed in ITER, are detailed.
Prologue v
1 Machine Architecture and Objectives
1(24)
1.1 Beginning of the ITER Project
1(2)
1.2 Architecture of ITER
3(15)
1.2.1 Operational regimes documented by tokamak experiments
9(2)
1.2.2 Why is ITER so important for future generations?
11(3)
1.2.3 Elementary description of the plasma turbulence
14(4)
1.3 Plasma Heaters NBI, ICRH LHCD and ECRH
18(7)
References
21(4)
2 Magnetohydrodynamic Description of the Equilibrium and Heating of the Thermal Plasma
25(22)
2.1 Equilibrium with Single Lower-Null X-point Divertor
25(4)
2.2 The Single-Fluid Magnetohydrodynamic Model
29(3)
2.3 Grad-Shafranov MHD Equilibrium for Axisymmetric Systems
32(2)
2.4 Particle Energy Distributions
34(1)
2.5 Magnetic Reconnection from Resistive MHD Dynamics
35(1)
2.6 Vertical Displacement Instabilities and Halo Currents
36(1)
2.7 Electron Temperature Gradient-Driven Turbulence
37(1)
2.8 High-Energy Electron Distributions from RF Heating and Toroidal Plasma Currents
37(10)
References
43(4)
3 Alfven Cavity Modes, Fast Ions, Alpha Particles and Diagnostic Neutral Beams
47(16)
3.1 Plasma Eigenmodes and their Destabilization by High-Energy Ions
48(2)
3.2 Loss Process for High-Energy Ions and Electrons
50(5)
3.3 Diagnostic Neutral Beam Injection
55(3)
3.4 Resistive Wall Modes
58(5)
References
59(4)
4 Turbulent Transport from the Temperature Gradients
63(34)
4.1 Drift Wave Instabilities from Density and Pressure Gradients
65(5)
4.1.1 Drift wave frequencies and instabilities from density and temperature gradients
67(1)
4.1.2 Instabilities from magnetic curvature and toroidal plasma currents
67(3)
4.2 Ballooning-Interchange Modes and Resistive-g Modes
70(1)
4.3 Temperature Gradient Instabilities Driving Turbulent Thermal and Density Transport
71(3)
4.4 Electron Temperature Gradient-Driven Transport Instabilities Producing Anomalously Low-Electron Temperatures and Regions of Ergodic/Stochastic Magnetic Field Lines
74(6)
4.5 Thermodynamic Properties of Electron Temperature Gradient Driven Transport
80(17)
4.5.1 Two-space scales for electron transport
82(4)
4.5.2 Nonadiabatic ion response
86(1)
4.5.3 Electron thermal transport in TCV
87(1)
4.5.4 Average relative variance (ARV)
88(3)
References
91(6)
5 Operational Regimes and their Properties
97(52)
5.1 Ohmic Plasma Confinement Mode, H-mode, I-mode Plasmas
97(3)
5.2 Control of Confinement Modes with External Sources of Momentum and Energy Injectors
100(1)
5.3 Bifurcations Models Describing Spontaneous Symmetry Breaking with Transitions to L, H and ELMy-H Modes
101(1)
5.4 Hot Ion Mode Sets Record
102(1)
5.5 Discovery of Edge Localized Modes (ELMs)
103(1)
5.6 Comparison of Four Confinement Modes in a Long Discharge
104(19)
5.6.1 ECRH driven discharges
106(17)
5.7 Edge Localized Modes and Plasma Pedestals
123(2)
5.8 Thermodynamics of the ITG Instability
125(9)
5.9 Isotope Scaling of Energy Confinement Time
134(6)
5.10 Visualization of the Coherent Structures in ELMy Discharges
140(9)
References
143(6)
6 Transport Barriers and ELM Control
149(18)
6.1 Record DT Fusion Power Discharges in the Joint European Torus (JET)
149(1)
6.2 Radial Electric Field Er in H-mode Transport Barriers
150(1)
6.3 Internal Transport Barriers from ITG/TEM Turbulence
151(5)
6.3.1 Predator-prey models
152(3)
6.3.2 Computer simulations for interaction of the zonal flows and the drift wave turbulence
155(1)
6.4 ELM Control with Resonant Magnetic Perturbation
156(3)
6.5 ELM Control with Pellet Injection
159(8)
6.5.1 Database on fuel retention in present fusion devices
163(1)
References
164(3)
7 Steady-State Operation
167(26)
7.1 Neoclassical Bootstrap Current
169(3)
7.2 Scattering of Radio Frequency-RF Waves in Turbulent Plasmas
172(1)
7.3 ELM Control for Steady-State Plasma Operation with Resonant Magnetic Perturbations
173(4)
7.3.1 Resistive MHD normalization
175(1)
7.3.2 RMP simulations with the 3D resistive MHD model
176(1)
7.4 Helical Equilibrium Plasma States Created by the External RMP Currents
177(6)
7.4.1 Transition to the rotating state with strong convective flux
179(4)
7.5 Rotating States in Toroidal Geometry with Multiple RMPs
183(1)
7.6 Issues with RMP for Controlling ELMs
184(1)
7.7 RF Driven Anisotropic High Energy Electron Phase-Space Distribution Functions
185(8)
References
189(4)
8 Plasma Diagnostics
193(16)
8.1 Plasma Spectroscopy
194(1)
8.2 Beam induced Plasma Spectroscopy
195(2)
8.3 Charge Exchange Recombination Spectroscopy
197(2)
8.4 Energy Distribution Functions for Electrons, Ions and Alpha Particles
199(1)
8.5 Scattering of High-Frequency Electromagnetic Waves from Plasmas
200(2)
8.5.1 Scattering of RF waves in the turbulent plasma
201(1)
8.6 Magnetic Probes
202(1)
8.7 X-ray Spectra and Electron Cyclotron Emission
203(1)
8.8 Langmuir Probes
203(3)
8.8.1 Pellet injection as a diagnostic probe
204(1)
8.8.2 Alpha particle and neutron detectors
205(1)
8.9 Gas Puff Imagining and Phase Contrast Imaging
206(3)
References
207(2)
9 Plasma Facing Components and Plasma-Wall Interaction Physics
209(12)
9.1 Crystallization and Melting Limits
210(3)
9.2 Wall Erosion Due to Evaporation
213(1)
9.3 Wall Blistering Below the Melting Temperature
213(1)
9.4 Radiation Limits for Fusion Reactors
214(1)
9.5 International Fusion Materials Irradiation Facility (IFMIF)
215(1)
9.6 Lifetime of Wall and Divertor Elements
216(1)
9.7 Surface Quantum Physics
217(4)
References
218(3)
10 The Broader Approach and Tritium Breeding Blankets
221(10)
10.1 Neutron Blanket and Breeding Tritium
221(1)
10.2 The Broader Approach and IFMIF
222(1)
10.3 Neutron Shielding, the Cryostat and the Cooling Systems
223(2)
10.4 Steady-State High Beta-High Fluence Machine
225(1)
10.5 Radiation Diagnostics, Neutron and Hard X-ray Radiation Monitoring and Remote Handling for Maintenance
226(5)
References
228(3)
Glossary Index 231(2)
General Index 233