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Mesoscale modelling of crack nucleation from defects in steel
Eeva Mikkola
, Gary Marquis
*
, Jussi Solin
*
Corresponding author for this work
Aalto University
Research output
:
Contribution to journal
›
Article
›
Scientific
›
peer-review
21
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Citations (Scopus)
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Keyphrases
Crack nucleation
100%
Element-by-element
50%
Endurance Limit
50%
Fatigue Strength
50%
Finite Element
50%
Grain Defects
50%
Grain Orientation
50%
Grain Size
50%
High Strength Steel
50%
Individual Grains
50%
Long-term Fatigue
50%
Low Stress
50%
Material Volume
50%
Mesoscale Models
100%
Microcrack nucleation
50%
Microcrack Propagation
50%
Non-metallic Inclusions
50%
Nucleation Model
50%
Plastic Shear Strain
50%
Polycrystalline Materials
50%
Propagation Model
50%
Shear Stress
50%
Size Scaling
50%
Stress Amplitude
50%
INIS
amplitudes
20%
cracks
100%
defects
100%
fatigue
20%
finite element method
20%
grain orientation
20%
grain size
20%
inclusions
20%
modeling
100%
nucleation
100%
orientation
20%
plastics
20%
polycrystals
20%
range
20%
shear
40%
size
20%
steels
100%
strains
40%
volume
20%
Engineering
Endurance Limit
50%
Fatigue Strength
50%
Finite Element Analysis
50%
Grain Orientation
50%
High Strength Steels
50%
Individual Grain
50%
Material Volume
50%
Mesoscale
100%
Nonmetallic Inclusion
50%
Polycrystalline Material
50%
Propagation Model
50%
Shear Strain
50%
Size Scale
50%
Stress Amplitude
50%
Material Science
Fatigue of Materials
50%
Finite Element Methods
50%
Grain Size
50%
High Strength Steels
50%
Non-Metallic Inclusions
50%
Nucleation
100%
Polycrystalline Material
50%
Shear Strain
50%