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Modeling creep and fatigue of copper alloys
G. Li, B. G. Thomas,
J. F. Stubbins
Nuclear, Plasma, and Radiological Engineering
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Keyphrases
Creep
100%
Copper Alloy
100%
Thermal Creep
66%
Aluminum Oxide
33%
Finite Element Model
33%
Two Dimensional
33%
Cu-Ag
33%
Strain Rate
33%
Loading Conditions
33%
Mechanical Behavior
33%
Fatigue Load
33%
Two-layer
33%
Stainless Steel
33%
Structure Behavior
33%
Stress Level
33%
Cu-Ni
33%
Fusion Reactor
33%
Fatigue Life
33%
High Heat Flux
33%
Thermal Fatigue
33%
First Wall
33%
Continuous Steel Casting
33%
Property Model
33%
ABAQUS Software
33%
Heat Exhaustion
33%
Alloy Steel
33%
Ratchetting
33%
CuCrZr
33%
Cu-Al2O3
33%
Elastic-plastic-creep
33%
Creep Lifetime
33%
Creep Law
33%
Four-point Bending Fatigue Test
33%
Engineering
Creep
100%
Thermal Creep
100%
Review Article
50%
Finite Element Modeling
50%
Two Dimensional
50%
Heat Flux
50%
Point Bending
50%
Strain Rate
50%
Mechanical Fatigue Test
50%
Stainless Steel
50%
Test Specimen
50%
Stress Level
50%
Fusion Reactor
50%
Structural Behavior
50%
Thermal Fatigue
50%
Alloy Steel
50%
Continuous Casting
50%
Fatigue Lifetime
50%
Fatigue Loading Condition
50%
Creep Lifetime
50%
Material Science
Creep
100%
Copper Alloys
100%
Al2O3
66%
Thermal Creep
66%
Finite Element Modeling
33%
Strain Rate
33%
Mechanical Property
33%
Stainless Steel
33%
Alloy Steel
33%
Structural Behavior
33%
Thermal Fatigue
33%