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Micromechanical modeling of damage in elasto-plastic nanocomposites using unit cell representative volume element and cohesive zone model
M. A. Eltaher, A. Wagih
Research output
:
Contribution to journal
›
Article
›
peer-review
20
Scopus citations
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Dive into the research topics of 'Micromechanical modeling of damage in elasto-plastic nanocomposites using unit cell representative volume element and cohesive zone model'. Together they form a unique fingerprint.
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Engineering
Representative Volume Element
100%
Cohesive Zone Model
100%
Nanocomposites
100%
Micromechanical Modeling
100%
Stress-Strain Relations
25%
Cohesive Element
25%
Interfacial Bonding
25%
Element Model
25%
Matrix Phase
25%
Microstructure
12%
Experimental Result
12%
Decohesion
12%
Damage Behavior
12%
High-Energy Ball Milling
12%
Bonded Interface
12%
Cohesive Interface Element
12%
Interface Strength
12%
Nanoparticle Reinforcement
12%
Sintering
12%
Material Science
Cohesive Zone Model
100%
Nanocomposites
100%
Al2O3
37%
Stress-Strain Relations
25%
Nanoparticle
12%
Sintering
12%
Keyphrases
Cohesive Element Model
66%
Reinforcement Phase
66%
Cohesive Interface Element
33%
Real Microstructure
33%
Interface Strength
33%