Editor in chief......Page 1
Section editors......Page 2
Copyright......Page 3
Editors biographies......Page 4
Preface......Page 6
References......Page 303
4.01.3.2 Irradiation Creep......Page 10
4.01 Radiation Effects in Zirconium Alloys......Page 14
4.01.1.1 Damage Creation: Short-Term Evolution......Page 15
4.01.3.2.1 Irradiation creep: Macroscopic behavior......Page 37
4.01.3.2.2 Irradiation creep: Mechanisms......Page 38
4.01.3.3 Outlook......Page 39
References......Page 40
4.02 Radiation Damage in Austenitic Steels......Page 45
4.03 Ferritic Steels and Advanced FerriticΒ
MartensiticSteels......Page 108
4.04 Radiation Effects in Nickel-Based Alloys......Page 133
Acknowledgments......Page 158
4.05 Radiation Damage of Reactor Pressure Vessel Steels......Page 161
4.08.9 Summary......Page 191
4.07 Radiation Effects in SiC and SiCΒ
SiC......Page 224
4.08 Oxide Dispersion Strengthened Steels......Page 250
4.08.8.3.1 9Cr- and 12Cr-ODS steel cladding in BOR-60......Page 277
4.08.8.3.2 12Cr-ODS steel cladding in EBR-II......Page 278
4.09 Welds for Nuclear Systems......Page 281
4.10 Radiation Effects in Graphite......Page 307
4.11.20.6.3 Further modifications to the UKAEA creep law: interaction strain......Page 333
4.11.21 Concluding Remark......Page 395
4.12 Vanadium for Nuclear Systems......Page 399
4.13 Concrete......Page 415
4.14 Fracture Toughness Master Curve of bcc Steels......Page 440
4.15 Ceramic Breeder Materials......Page 469
4.16 Tritium Barriers and Tritium Diffusion inFusion Reactors......Page 517
4.17 Tungsten as a Plasma-Facing Material......Page 556
4.18 Carbon as a Fusion Plasma-Facing Material......Page 587
4.19 Beryllium as a Plasma-Facing Material for Near-TermFusion Devices......Page 625
4.20 Physical and Mechanical Properties of Copper andCopper Alloys......Page 671
4.21 Ceramic Coatings as Electrical Insulators in FusionBlankets......Page 695
4.22 Radiation Effects on the Physical Properties ofDielectric Insulators for Fusion Reactors......Page 704
