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Transformation superplasticity of iron and Fe/TiC metal matrix composites
Peter Zwigl
*
,
David C. Dunand
*
Corresponding author for this work
Materials Science and Engineering
Research output
:
Contribution to journal
›
Article
›
peer-review
36
Scopus citations
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Keyphrases
Fe-TiC
100%
Superplasticity
100%
Metal Matrix Composites
100%
Strain Increment
100%
Phase Field
33%
Yield Stress
33%
TiC Particles
33%
Superplastic
33%
Temperature Range
16%
Iron Oxide
16%
Fracture Strain
16%
Solid Solution Strengthening
16%
Oxide Dispersoids
16%
Temperature Cycling
16%
External Stress
16%
Stress-strain
16%
Austenite
16%
Primary Creep
16%
Strain Hardening
16%
Allotropic
16%
Uniaxial Tensile Stress
16%
Unreinforced
16%
Transformation Temperature
16%
Total Strain
16%
Ferrite
16%
Carbon Oxides
16%
Measured Strain
16%
Strain Behavior
16%
Dissolved Carbon
16%
Smaller Stresses
16%
Ratchetting
16%
TiC Content
16%
Dissolved Iron
16%
Iron Matrix Composite
16%
Partial Cycle
16%
Engineering
Strain Increment
100%
Metal Matrix Composite
100%
Applied Stress
50%
Phase Field
33%
Yield Point
33%
Primary Creep
16%
Dispersoid
16%
Tensile Stress σ
16%
Temperature Range
16%
Iron Matrix
16%
External Stress
16%
Measured Strain
16%
Fracture Strain
16%
Internals
16%
Transients
16%
Strain Behavior
16%
Austenite
16%
Solid Solutions
16%
Strain Hardening
16%
Material Science
Superplasticity
100%
Metal Matrix Composite
100%
Yield Stress
66%
Work Hardening
33%
Iron Oxide
33%
Matrix Composite
33%
Austenite
33%
Primary Creep
33%
Ultimate Tensile Strength
33%
Solid Solutions
33%