Impact resistance of nanocellulose films with bioinspired Bouligand microstructures

INIS

• nanocrystals 100%
• films 83%
• performance 83%
• pitch angle 83%
• cellulose 66%
• microstructure 50%
• design 33%
• thin films 33%
• layers 33%
• cracks 33%
• processing 16%
• lasers 16%
• biological materials 16%
• interactions 16%
• simulation 16%
• optimization 16%
• molecular dynamics method 16%
• velocity 16%
• nanomaterials 16%
• solvents 16%
• fibers 16%
• loading 16%
• aspect ratio 16%
• energy dissipation 16%
• energy absorption 16%
• thickness 16%
• fragmentation 16%
• projectiles 16%
• impact tests 16%

Engineering

• Pitch Angle 83%
• Performance 83%
• Cellulose Nanocrystals 66%
• Microstructure 50%
• Impact Resistance 50%
• Thin Films 33%
• Interlayer 33%
• Computer Simulation 16%
• Nanomaterial 16%
• Energy Dissipation 16%
• Crack Opening 16%
• High Aspect Ratio 16%
• Energy Absorption 16%
• Coarse-Grained Molecular Dynamic 16%
• Mechanical Design 16%
• Impact Test 16%
• Interfacial Interaction 16%
• Plywood 16%
• Development 16%
• Design 16%
• Processing 16%
• Events 16%
• Models 16%
• Measurer 16%
• Fiber 16%
• Mechanisms 16%
• Crack 16%
• Thickness 16%
• Nanocellulose Film 16%

Material Science

• Liquid Films 66%
• Impact Resistance 50%
• Microstructure 50%
• Thin Films 33%
• Velocity 33%
• Biomaterial 16%
• Nanostructured Material 16%
• Nanocrystalline Material 16%
• Plywood 16%
• Material 16%
• Solvent 16%
• Laser 16%
• Fiber 16%
• Crack 16%