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Modeling fatigue crack growth resistance of nanocrystalline alloys
Piyas B. Chowdhury
,
Huseyin Sehitoglu
, Richard G. Rateick
, Hans J. Maier
Mechanical Science and Engineering
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peer-review
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Keyphrases
Nanocrystalline Alloys
100%
Fatigue Crack Growth
100%
Fatigue Crack Growth Resistance
100%
Modelling Fatigue
100%
Crack Tip
50%
Energy Barrier
50%
Dislocation Glide
50%
Coherent Twin Boundary
50%
Continuum Approach
25%
Physical Processes
25%
Twin Boundary
25%
Atomistic-to-continuum
25%
Dislocation Slip
25%
Mechanics Model
25%
Forward Flow
25%
Reverse Flow
25%
Crack Advance
25%
Crack Tip Displacement
25%
Twin Spacing
25%
Twin Thickness
25%
Glide Dislocation
25%
Engineering
Nanocrystalline
100%
Fatigue Crack Growth
100%
Crack Tip
50%
Energy Barrier
33%
Dislocation Glide
33%
Irreversibility
33%
Nanoscale
16%
Simulation Result
16%
Mechanic Model
16%
Continuum Approach
16%
Experimental Finding
16%
Reverse Flow
16%
Crack Advance
16%
Material Science
Nanocrystalline Alloys
100%
Fatigue Crack Growth
100%
Crack Tip
50%