Mixed-dimensional modeling of delamination in rare earth-barium-copper-oxide coated conductors composed of laminated high-aspect-ratio thin films

Keyphrases

• High Aspect Ratio 100%
• Delamination 100%
• Coated Conductor 100%
• Mixed Dimensional Modeling 100%
• Full Three-dimensional 50%
• Mixed-dimensional 50%
• Two-dimensional Surface 33%
• Cohesive Zone Model 33%
• 3D FEM 33%
• Oxide Conductor 33%
• High Energy 16%
• High Field 16%
• Three-dimensional (3D) 16%
• Stress Distribution 16%
• Finite Element Method 16%
• Stabilizer 16%
• Epoxy 16%
• Initiation Site 16%
• Buffer Layer 16%
• High-temperature Superconductivity 16%
• Computational Problems 16%
• Anvil 16%
• Field Temperature 16%
• Thickness Dependence 16%
• Delamination Modeling 16%
• High Computational Efficiency 16%
• Load Capacity 16%
• Delamination Behavior 16%
• Transverse Stress 16%
• Delamination Initiation 16%
• Adjacent Layers 16%
• Lorentz Force 16%
• Mixed-dimensional Model 16%
• Superconducting Coils 16%
• Superconducting Applications 16%

Engineering

• Thin Films 100%
• High Aspect Ratio 100%
• Dimensional Modeling 100%
• Delamination 100%
• Finite Element Analysis 50%
• Two Dimensional 33%
• Dimensional Surface 33%
• Cohesive Zone Model 33%
• Simulation Result 16%
• Thin Layer 16%
• Oxide Layer 16%
• Buffer Layer 16%
• Load Limits 16%
• Dimensional Model 16%
• Computational Efficiency 16%
• Stabilizer 16%
• Generated Stress 16%
• Adjacent Layer 16%
• Dimensional Method 16%
• Lorentz Force 16%
• Initial Crack Size 16%
• Superconducting Coil 16%

Material Science

• Barium 100%
• Thin Films 100%
• Oxide Compound 100%
• Conductor 100%
• Delamination 100%
• Finite Element Method 42%
• Cohesive Zone Model 28%
• Composite Material 28%
• Silver 14%
• Stabilizer (Agent) 14%
• Buffer Layer 14%