《受控核聚变中的等离子体与材料的相互作用(影印版)》讨论的是受控核聚变中发生的物体的四种状态之中的等离子态与固态之间的相互作用。本书在给出主要的等离子体与表面的相互作用过程的综合分析的同时,也提出了对于操作极限的判断标准和依据。通过讨论,本书将受控核聚变中可能的面向等离子体材料限制在了很小的一个范围内。本书适合核物理、材料物理等领域的研究者和研究生阅读。
《中外物理学精品书系·引进系列(19):受控核聚变中的等离子体与材料的相互作用(影印版)》内容丰富,涵盖面广,可读性强,其中既有对我国传统物理学发展的梳理和总结,也有对正在蓬勃发展的物理学前沿的全面展示;既引进和介绍了世界物理学研究的发展动态,也面向国际主流领域传播中国物理的优秀专著。
1 Introduction
Part Ⅰ Fusion as Energy Source
2 Energy Problem and Related Safety Aspects
3 Fusion Fuel
3.1 Fusion Reactions
3.2 Ignition and Burn Criteria
4 Fusion Concepts
4.1 Inertial Plasma Confinement
4.2 Magnetic Plasma Confinement
4.3 Stellarator Concept
4.4 Tokamak Concept
4.5 Design of the First Wall
4.5.1 Limiter
4.5.2 Divertor
1 Introduction
Part Ⅰ Fusion as Energy Source
2 Energy Problem and Related Safety Aspects
3 Fusion Fuel
3.1 Fusion Reactions
3.2 Ignition and Burn Criteria
4 Fusion Concepts
4.1 Inertial Plasma Confinement
4.2 Magnetic Plasma Confinement
4.3 Stellarator Concept
4.4 Tokamak Concept
4.5 Design of the First Wall
4.5.1 Limiter
4.5.2 Divertor
Part Ⅱ The Plasma-Material Interface
5 The Plasma State
5.1 Ionization Degree and Coupling Constant
5.2 Debye Length
5.3 Plasma Frequency
5.4 Collisions in Plasmas
5.5 Transport Processes in Plasmas
5.5.1 Transport by Binary Collisions
5.5.2 Neoclassical Diffusion
5.5.3 Anomalous Transport
5.6 The Vlasov Equation
5.7 The Poisson Equation
6 Particle Coupling
6.1 Binary Collisions
6.1.1 Scattering Angle a
6.1.2 Scattering in the Coulomb Field, U (r) = C/r
6.1.3 Cross-Section
6.1.4 Interaction Potential U (r)
6.1.5 Binary Collision: General Case
6.2 Particle Transport in Matter
6.2.1 Definitions and Main Parameters
6.2.2 Elastic Energy Loss
6.2.3 Inelastic Energy Loss
6.3 Material Modification by Ion Beams
6.4 Retention and Tritium Inventory Control
6.5 Impurity Generation
6.5.1 Physical Sputtering
6.5.2 Chemical Erosion
6.5.3 Radiation-Enhanced Sublimation
6.5.4 Thermal Evaporation
6.5.5 Blistering
6.6 Charge Effects
6.7 Diffusion-Controlled Sputtering
6.8 Backscattering
6.8.1 One-Collision Model
6.8.2 The Diffusion Model
6.8.3 Approximations
6.9 Electron Emission
6.9.1 Secondary Electron Emission (SEE)
6.9.2 Thermionic Electron Emission
6.9.3 Electron Emission by the Application of an Electric Field
6.10 Modeling of Particle-Solid Interaction
6.10.1 Molecular Dynamics
6.10.2 Monte Carlo Methods
7 Electrical Coupling
7.1 Electron Flux Density
7.2 Ion Flux Density
7.3 Bohm Criterion with the “=” Sign
7.4 Space Charge Limited Currents
7.5 Effect of Magnetic Field Geometry
……
Part Ⅲ Operation Limits and Criteria
