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On modeling hydrogen-induced crack propagation under sustained load
Mohsen Dadfarnia
, Brian P. Somerday
, Philip E. Schembri
,
Petros Sofronis
, James W. Foulk
, Kevin A. Nibur
, Dorian K. Balch
Mechanical Science and Engineering
Materials Science and Engineering
Materials Research Lab
Grainger College of Engineering
Center for East Asian and Pacific Studies
Research output
:
Contribution to journal
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Article
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peer-review
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Keyphrases
Characteristic Distance
16%
Containment
16%
Crack Arrest
16%
Crack Growth Behavior
16%
Crack Propagation
100%
Crack Tip
16%
Developing Materials
16%
Diffusion Control
16%
Environmental Variables
16%
Finite Element Simulation
16%
Fracture Strength
33%
Hydrogen Diffusion
16%
Hydrogen Embrittlement
16%
Hydrogen Environment
16%
Hydrogen-induced Cracking
100%
Induced Stress
16%
K-curve
16%
Local Fracture
16%
Material Fracture
16%
Material Variables
16%
Numerical Simulation
16%
Opening Stress
16%
Stress Control
16%
Stress Intensity Factor
16%
Subcritical Crack Growth
16%
Subcritical Cracking
16%
Sustained Load
100%
Sustained Loading
16%
Engineering
Characteristic Distance
16%
Crack Arrest
16%
Crack Growth Behavior
16%
Crack Propagation
100%
Crack Tip
16%
Environmental Variable
16%
Finite Element Simulation
16%
Fracture Strength
33%
Hydrogen Embrittlement
16%
Induced Stress
16%
Model Material
16%
Resistant Material
16%
Stress-Intensity Factor
16%
Material Science
Crack Arrest
16%
Crack Growth
16%
Crack Propagation
100%
Crack Tip
16%
Finite Element Method
16%
Fracture Toughness
33%
Hydrogen Embrittlement
16%
Stress Intensity Factor
16%