Effect of microstructure evolution on fracture toughness in isothermally aged austenitic stainless steels for cryogenic applications

Engineering & Materials Science

• Cryogenics 90%
• Austenitic stainless steel 81%
• Fracture toughness 76%
• Microstructure 57%
• Aging of materials 51%
• Steel 49%
• Superconducting magnets 31%
• Experimental reactors 30%
• Microstructural evolution 26%
• Fracture energy 25%
• Nitrides 25%
• Temperature 25%
• Brittle fracture 24%
• Precipitates 22%
• Nuclear energy 22%
• Carbides 20%
• Electron microscopes 20%
• Toughness 20%
• Deterioration 19%
• Volume fraction 19%
• Fusion reactions 17%
• Scanning 16%

Physics & Astronomy

• austenitic stainless steels 100%
• fracture strength 85%
• cryogenics 80%
• steels 63%
• microstructure 50%
• superconducting magnets 23%
• notches 23%
• nuclear energy 23%
• cryogenic temperature 23%
• toughness 22%
• deterioration 22%
• Japan 22%
• carbides 20%
• nitrides 19%
• precipitates 18%
• fusion 17%
• electron microscopes 17%
• reactors 16%
• scanning 13%
• temperature 12%
• energy 6%

Chemistry

• Fracture Toughness 96%
• Cryogenics 94%
• Microstructure 57%
• Brittle Fracture 42%
• Fracture Energy 41%
• Time 30%
• Nitride 27%
• Application 27%
• Volume 16%
• Electron Particle 15%
• Energy 13%
• Reduction 13%