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Dynamics and stability of metallic foams: Network modeling
Peter S. Stewart
*
, Stephen H. Davis
*
Corresponding author for this work
Engineering Sciences and Applied Mathematics
Mechanical Engineering
Research output
:
Contribution to journal
›
Article
›
peer-review
15
Scopus citations
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Keyphrases
Network Model
100%
Metallic Foam
100%
Numerical Simulation
50%
Gas-liquid
50%
Capillary
50%
Suction
50%
Gas Bubble
50%
Processing Techniques
50%
Colloidal Particles
50%
Van Der Waals
50%
Breakage
50%
Thin Liquid Film
50%
Surfactant
50%
Large-scale Networks
50%
Liquid Film
50%
Porous Metal
50%
Direct Coupling
50%
Surface Tension Force
50%
Bubble Surface
50%
Bubble Coalescence
50%
Batch Processing
50%
Liquid Fraction
50%
Liquid Foam
50%
Plateau Border
50%
Coalescence Process
50%
Elongational Flow
50%
Liquid Draining
50%
Gas-liquid Interface
50%
Rectangular Box
50%
Liquid-free
50%
Engineering
Metallic Foam
100%
Liquid Gas
100%
Liquid Film
100%
Surface Tension Force
50%
Processing Technique
50%
Gas Bubble
50%
Scale Network
50%
Surfactant
50%
Porous Metal
50%
Liquid Fraction
50%
Bubble Coalescence
50%
Batch Processing
50%
Thin Films
50%
Network Model
50%
Breakage
50%
Colloidal Particle
50%
Computer Simulation
50%
Material Science
Film
100%
Coarsening
50%
Surface Active Agent
50%
Thin Liquid Film
50%
Liquid Interface
50%
Surface Tension
50%
Thin Films
50%
Liquid Film
50%
Chemical Engineering
Film
100%
Bubble Coalescence
20%
Surfactant
20%