Bahman Zohuri
Springer International Publishing
e druk, 2018
9783319845197
Inertial Confinement Fusion Driven Thermonuclear Energy
Specificaties
Paperback, blz.
|
Engels
Springer International Publishing |
e druk, 2018
ISBN13: 9783319845197
Rubricering
Verwachte levertijd ongeveer 9 werkdagen
Samenvatting
This book takes a holistic approach to plasma physics and controlled fusion via Inertial Confinement Fusion (ICF) techniques, establishing a new standard for clean nuclear power generation. Inertial Confinement Fusion techniques to enable laser-driven fusion have long been confined to the black-box of government classification due to related research on thermonuclear weapons applications. This book is therefore the first of its kind to explain the physics, mathematics and methods behind the implosion of the Nd-Glass tiny balloon (pellet), using reliable and thoroughly referenced data sources. The associated computer code and numerical analysis are included in the book. No prior knowledge of Laser Driven Fusion and no more than basic background in plasma physics is required.
Specificaties
ISBN13:9783319845197
Taal:Engels
Bindwijze:paperback
Uitgever:Springer International Publishing
Inhoudsopgave
<div>About the Author</div><div>Preface</div><div>Acknowledgment</div><div>CHAPTER ONE: Short Course in Thermal Physics and Statistical Mechanics</div><div>1.1 Introduction</div><div>1.2 Ideal Gas</div><div>1.3 Bose-Einstein Distribution Function</div><div>1.4 Fermi-Dirac Distribution Function</div><div>1.4.1 The Grand Partition Function and Other Thermodynamic Functions</div><div>1.4.2 The Fermi -- Dirac Distribution Function</div><div>1.5 Ideal Fermi Gas</div><div>1.6 Ideal Dense Plasma</div><div>1.6.1 Thermodynamic Relations</div><div>1.6.2 Ideal Gas and Saha Ionization</div><div>1.7 Thomas--Fermi Theory</div><div>1.7.1 Basic Thomas--Fermi Equations</div><div>1.8 References</div><div>CHAPTER TWO: Essential Physics of Inertial Confinement Fusion (ICF)</div><div>2.1 Introduction</div><div>2.2 General Concept of Electromagnetisms and Electrostatics</div><div>2.2.1 The Coulomb's Law</div><div>2.2.2 The Electric Field</div><div>2.2.3 The Gauss's Law</div><div>2.3 Solution of Electrostatic Problems</div><div>2.3.1 Poisson's Equation</div><div>2.3.2 Laplace's Equation</div><div>2.4 Electrostatic Energy</div><div>2.4.1 Potential Energy of a Group of Point Charges</div><div>2.4.2 Electrostatic Energy of a Charge Distribution</div><div>2.4.3 Forces and Torques</div><div>2.5 Maxwell's Equations</div><div>2.6 Debye Length</div><div>2.7 Physics of Plasmas</div><div>2.8 Fluid Description of Plasma</div><div>2.9 Magneto-Hydro Dynamics (MHD)</div><div>2.10 Physics of Dimensional Analysis Application in Inertial Confinement Fusion ICF</div><div>2.10.1 Dimensional Analysis and Scaling Concept</div><div>2.10.2 Similarity and Estimating</div><div>2.10.3 Self-Similarity</div><div>2.10.4 General Results of Similarity</div><div>2.10.5 Principles of Similarity</div><div>2.11 Self-Similarity Solutions of the First and Second Kind</div><div>2.12 Physics of Implosion and Explosion in ICF--Self-Similarity Methods</div><div>2.13 Self-Similarity and Sedov - Taylor Problem</div><div>2.14 Self-Similarity and Guderley Problem</div><div>2.15 References<</div><div>CHAPTER THREE: Physics of Inertial Confinement Fusion (ICF)</div><div>3.1 Introduction</div><div>3.2 Rates of Thermonuclear Reactions</div><div>3.3 Critical Ignition Temperature for Fusion</div><div>3.4 Controlled Thermonuclear Ideal Ignition Temperature</div><div>3.5 Lawson Criterion</div><div>3.5.1 Inertial Confinement and Lawson Criterion</div><div>3.6 Bremsstrahlung Radiation</div><div>3.6.1 Bremsstrahlung Plasma Radiation Losses</div><div>3.6.2 Bremsstrahlung Emission Rate</div><div>3.6.3 Additional Radiation Losses</div><div>3.6.4 Inverse Bremsstrahlung Radiation in Inertial Confinement Fusion</div><div>3.7 Rayleigh-Taylor Instability in Inertial Confinement Fusion</div><div>3.8 Richtmyer-Meshkov Instability in Inertial Confinement Fusion</div><div>3.9 Filamentation Instability in Inertial Confinement Fusion</div><div>3.10 Kelvin-Helmholtz Instability</div><div>3.11 References</div><div>CHAPTER FOUR: Inertial Confinement Fusion (ICF)</div><div>4.1 Introduction</div><div>4.2 Overview of Inertial Confinement Fusion (ICF)</div><div>4.3 Inertial Confinement Fusion (ICF) Process Steps</div><div>4.4 A Path Towards Inertial Fusion Energy</div><div>4.4.1 Direct Drive Fusion</div><div>4.4.2 Indirect Drive Fusion (The Hohlraum)</div><div>4.4.3 Single Beam Driver as Ignitor Concept (Fast Ignition)</div><div>4.5 Inertial Fusion Confinement Implosion and Explosion Process</div><div>4.5.1 Linear Compression Concept</div><div>4.5.2 Cylindrical Compression Concept</div><div>4.5.3 Spherical Compression Concept</div><div>4.6 Basic Consideration for Fusion Target Design</div><div>4.7 Targets for Direct-Drive Laser Inertial Fusion Energy</div><div>4.8 Z-Pinch Target</div><div>4.9 Target Fabrication</div><div>4.10 Conclusion</div><div>4.11 References</div><div>Appendix A: Schrödinger Wave Equation</div><div>A.1 Introduction</div><div>A.2 The Time-Dependent Schrödinger Equation Concept</div><div>A.3 Time-Independent Schrödinger Equation Concept</div><div>A.4 A Free Particle inside a Box and Density of State</div><div>A.5 Heisenberg Uncertainty Principle</div><div>A.6 Pauli Exclusion Principle</div><div>Appendix B: The Stirling Formula</div><div>B.1 Proof of Stirling's Formula</div><div>Appendix C: Table of Fermi--Dirac Functions</div><div>C.1 Fermi-Dirac Functions</div><div>C.2 References</div><div>Appendix D: Tables of Thomas--Fermi Corrected Equation of State</div><div>Appendix E: Lagrangian and Eulerian Coordinate Systems</div><div>E.1 Introduction<div>E.2 Arbitrary Lagrangian Eulerian (ALE) Systems</div><div>E.3 References</div><div>Appendix F: Angular Plasma Frequency and High Power Laser</div><div>F.1 Plasma Frequency Introduction</div><div>F.2 High-Power Laser Fields Introduction</div><div>F.3 References</div><div>Appendix G: A Soliton Wave</div><div>G.1 Introduction</div><div>G.2 References</div><div>INDEX</div>