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On the origins of fatigue strength in crystalline metallic materials
J. C. Stinville
,
M. A. Charpagne
, A. Cervellon
, S. Hemery
, F. Wang
, P. G. Callahan
, V. Valle
, T. M. Pollock
Materials Research Lab
Materials Science and Engineering
Mechanical Science and Engineering
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peer-review
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Keyphrases
Metallic Materials
100%
Fatigue Strength
100%
Slip Localization
60%
Yield Strength
20%
Physical Characteristics
20%
Large Volume
20%
Physical Origin
20%
Nanometer Resolution
20%
Hexagonal Close-packed
20%
Deformation Process
20%
First Cycle
20%
Metallic Alloys
20%
Quantitative Relationship
20%
Rapid Methods
20%
Face-centered Cubic
20%
Materials Experience
20%
Body-centered Cubic
20%
Large Set
20%
Ultimate Tensile Strength
20%
Local Slip
20%
Irreversible Deformation
20%
Fatigue Failure
20%
Strength Characteristics
20%
Cyclic Deformation
20%
Fatigue Law
20%
Engineering
Fatigue Strength
100%
Early Stage
20%
Fatigue Failure
20%
Nanometre
20%
Body-Centered Cubic
20%
Applied Stress
20%
Face-Centered Cubic
20%
Hexagonal Close Packed
20%
Ultimate Tensile Strength
20%
Deformation Process
20%
Material Experience
20%
Physical Basis
20%
Irreversible Deformation
20%
Yield Point
20%
Material Science
Yield Stress
100%
Ultimate Tensile Strength
100%