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دانلود کتاب Plasma-Material Interactions in a Controlled Fusion Reactor (Springer Series in Plasma Science and Technology)
دانلود کتاب فعل و انفعالات پلاسما-مادی در یک راکتور فیوژن کنترل شده (سری Springer در علم و فناوری پلاسما)
مشخصات کتاب
Plasma-Material Interactions in a Controlled Fusion Reactor (Springer Series in Plasma Science and Technology)
ویرایش:
نویسندگان: Tetsuo Tanabe
سری:
ISBN (شابک) : 9811603278, 9789811603273
ناشر: Springer
سال نشر: 2021
تعداد صفحات: 219
[209]
زبان: English
فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود)
حجم فایل: 13 Mb
قیمت کتاب (تومان) : 75,000
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توضیحاتی درمورد کتاب به خارجی
فهرست مطالب
Preface Acknowledgements Contents Part IFusion Reactor and Plasma Material Interactions 1 Introduction 1.1 The Organization of This Book 1.2 Plasma–Material Interactions Caused by Power Load of Radiation and Energetic Particles 1.3 Energy Conversion from Nuclear to Thermal for Electric Power Generation 1.4 Brief History of the Development of Plasma-Facing Materials 1.5 On PMI Studies for a Fusion Reactor References 2 Discharges in Current Large Tokamaks 2.1 Introduction 2.2 Discharges of Current Large Tokamaks 2.3 Diagnostics for PMI Research 2.3.1 Optical Spectroscopy 2.3.2 Probe Measurements 2.4 PMI Observed by Proves and Limiter Experiments References 3 Power Load on Plasma-Facing Materials 3.1 Introduction 3.2 Estimation of Power Load and Its Distribution in a Fusion Reactor 3.3 Steady-State Power Load 3.4 Transient Power Load 3.5 Power Load by Neutrons 3.6 Mitigation of Power Load (Power Exhaust) References Part IIBasic Processes in PMI 4 Responses of Plasma-Facing Surface to Power Load Given by Radiation and Energetic Particles 4.1 Introduction 4.2 Energy Loss Processes of Energetic Particles Injected in a Solid Target 4.3 Emission of Ions and Neutrals 4.3.1 Reflection 4.3.2 Physical Sputtering 4.3.3 Chemical Sputtering 4.3.4 Ion-induced Desorption and Radiation-Enhanced Sublimation 4.4 Emission of Electrons and Photons 4.4.1 Electron Emission 4.4.2 Photon Emission 4.5 Energy Reflection 4.6 Reemission of Incident Ions 4.6.1 Reemission of Hydrogen (Fuel) 4.6.2 Reemission of Inert Gas Atoms 4.7 Interaction of Released Particles with Photons and Electrons in Boundary Plasmas 4.8 Summary References 5 Erosion and Deposition, and Their Influences on Plasma Behavior (Material Transport in Tokamak) 5.1 Introduction 5.2 Erosion, Transport, and Deposition 5.3 Formation of Deposited Layers Made of Eroded Materials 5.3.1 Carbon Wall 5.3.2 Metallic Wall 5.4 Summary References 6 Material Modification by High-Power Load and Its Influence on Plasma 6.1 Power Load to PFM 6.2 Material Response to Power Load and Its Influences on Boundary Plasmas 6.2.1 Spontaneous Response to Power Load 6.2.2 Melting and Sublimation 6.2.3 Hydrogen Recycling 6.3 Damaging and Degradation of PFM 6.3.1 Carbon (C) 6.3.2 Tungsten (W) 6.3.3 Other PFM Candidates (Be and Li) 6.3.4 Structure Materials 6.4 Summary References 7 Fundamentals of Hydrogen Recycling 7.1 Introduction 7.2 Overall Fuel Flow at Steady-State Burning 7.3 Injection of Energetic Hydrogen 7.4 Reflection, Reemission, and Retention 7.5 Permeation 7.6 Isotope Effects 7.7 Long-Term Retention and Trapping 7.8 Simulation and Modeling 7.9 Summary References Part IIIPMI, Observations in Present Large Tokamaks and Prospects in a Reactor 8 PMI in Large Tokamaks 8.1 Power Load 8.1.1 Power Load in JET 8.1.2 Exchange of PFM from Carbon to High Z Metals 8.1.3 ITER-Like Wall (ILW) in JET 8.1.4 Power Load by High Energy Particles Produced by Fusion 8.2 Erosion and Deposition 8.2.1 Carbon Wall (C-Wall) 8.2.2 Metallic Wall 8.3 Dust 8.4 Recycling and Retention of Fuels 8.4.1 Consideration of Fuel Retention Rate 8.4.2 Recycling 8.4.3 Long Term Fuel Retention 8.5 T-Related Issues on the In-Vessel T Inventory 8.6 Summary References 9 Fuel Retention in a Reactor with Full C-Wall and Full W-Wall and Its Recovery 9.1 Introduction 9.2 Present Estimation of Fuel Retention in ITER 9.3 Construction of Fuel Retention Model in a Fusion Reactor 9.4 Fuel Retention in Carbon Materials 9.4.1 Characteristics of Hydrogen Retention in Carbon Materials [11] 9.4.2 Fuel Retention Build-Up in JT-60U, a Full Carbon Wall Tokamak 9.4.3 Estimation of Carbon Deposition and Fuel Retention in an ITER Scale Full Carbon Reactor Operated at Around 600 K 9.5 Fuel Retention in Tungsten (W) 9.5.1 Characteristics of Hydrogen in W 9.5.2 Fluence Dependence of H Retention in W 9.6 Comparison of Estimated Fuel Retention in a Reactor with Full C-Wall and W-Wall 9.7 Fuel Removal/Recovery 9.7.1 Removal/Recovery of T Retained in Carbon Materials 9.7.2 Removal/Recovery of T Retained in W 9.8 Summary References 10 Selection of Plasma-Facing Materials 10.1 Criteria for Selection of PFM 10.2 Concerns on W Usage as PFM 10.3 Use of Carbon Materials as PFM 10.3.1 Character of C as PFM 10.3.2 Possible Use of C as PFM in a Reactor 10.4 Liquid PFM 10.5 Consideration of T Fuel on the Selection of PFM in a Reactor 10.6 Summary References 11 Closing Remarks Index
