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A composite model of nanocrystalline materials
George J. Weng
School of Engineering, Mechanical & Aerospace Engineering
Research output
:
Chapter in Book/Report/Conference proceeding
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Chapter
4
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Scopus citations
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Dive into the research topics of 'A composite model of nanocrystalline materials'. Together they form a unique fingerprint.
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Keyphrases
Nanocrystalline Materials
100%
Composite Model
100%
Stress-strain Relationship
66%
Grain Size
66%
Grain Boundary
66%
Activation Volume
66%
Grain Boundary Sliding
66%
Strain Rate Sensitivity
66%
Enhanced Sensitivity
33%
Molecular Dynamics Simulation
33%
Volume Change
33%
Affected Area
33%
Constituent Phase
33%
Unified Theory
33%
Flow Stress
33%
Power Law
33%
Constitutive Equation
33%
Size Reduction
33%
Volume Decrease
33%
Secant
33%
Field Fluctuations
33%
Stress Rate
33%
Homogenization Scheme
33%
General Trends
33%
Grain Interior
33%
Strain Rate Dependence
33%
Nanometre
33%
Viscosity Variation
33%
GB Sliding
33%
Nonlinear Strain
33%
Flow Strain
33%
Dislocation Theory
33%
Viscoplastic Behavior
33%
Soft Grains
33%
Heterogeneous Problems
33%
Engineering
Nanomaterial
100%
Nanocrystal
100%
Stress-Strain Relations
66%
Activation Volume
66%
Grain Boundary Sliding
66%
Strain Rate Sensitivity
66%
Strain Rate
33%
Fluid Viscosity
33%
Nanometre
33%
Constitutive Equation
33%
Test Result
33%
Flow Stress
33%
Affected Zone
33%
Grain Interior
33%
Computer Simulation
33%
Material Science
Strain Rate
100%
Composite Material
100%
Nanocrystals
100%
Stress-Strain Relations
66%
Grain Size
66%
Grain Boundary Sliding
66%
Grain Boundary
66%
Homogenization
33%
Viscoplastic Behavior
33%