Bio-Nanocomposite Jute Fibre Epoxy With Hybrid Seaweed and MWCNT Fillers: Development and Tribological Optimization

INIS

• nanocomposites 100%
• fibers 100%
• optimization 100%
• hybrids 100%
• seaweeds 100%
• carbon nanotubes 100%
• epoxides 100%
• fillers 100%
• jute 100%
• performance 66%
• friction 66%
• engineering 50%
• velocity 50%
• losses 50%
• nanotechnology 50%
• resources 50%
• wear 50%
• applications 33%
• values 33%
• industry 33%
• nanostructures 33%
• packaging 33%
• sustainable development 33%
• wear resistance 33%
• solutions 16%
• cities 16%
• devices 16%
• communities 16%
• production 16%
• validation 16%
• polymers 16%
• surfaces 16%
• apparatus 16%
• design 16%
• metals 16%
• capacity 16%
• composite materials 16%
• interfaces 16%
• distance 16%
• climates 16%
• graphene 16%
• energy storage 16%
• environmental impacts 16%
• lead oxides 16%

Engineering

• Carbon Nanotubes 100%
• Nanocomposites 100%
• Kenaf Fibre 100%
• Coefficient of Friction 75%
• Engineering 50%
• Frictional Force 50%
• Renewables 50%
• Sustainable Development Goals 50%
• Engineering Application 25%
• Tribological Performance 25%
• Wear Resistance 25%
• Friction Force 25%
• Material Performance 25%
• Filler Content 25%
• Durables 25%
• Support Material 25%
• Pin-on-Disc 25%
• Sliding Distance 25%
• Sliding Velocity 25%
• Graphene 25%
• Biomedical Device 25%
• Energy Storage 25%
• Resistant Material 25%
• Response Surface Methodology 25%
• Composite Material 25%
• Technological Development 25%
• Biopolymer 25%
• Fiber 25%
• Maximum load capacity 25%
• Friction Value 25%

Material Science

• Jute Fiber 100%
• Carbon Nanotubes 100%
• Nanocomposite 100%
• Coefficient of Friction 75%
• Composite Material 50%
• Composite Material 25%
• Fiber 25%
• Metal Oxide 25%
• Graphene Oxide 25%
• Polymer Composite 25%
• Epoxy 25%
• Tribological Performance 25%
• Wear Resistance 25%
• Advanced Material 25%
• Materials Engineering 25%
• Biopolymer 25%