Effects of recycled carbon fibers on mechanical and piezoresistive properties and environmental impact in alkali-activated cementitious materials

Keyphrases

• Mechanical Properties 100%
• Environmental Impact 100%
• Piezoresistive Properties 100%
• Alkali-activated Cement 100%
• Property Impact 100%
• Recycled Carbon Fiber 100%
• Ground Granulated Blast Furnace Slag (GGBFS) 30%
• Vol% 20%
• Solid Waste 20%
• Slurry 10%
• Cost Reduction 10%
• Carbon Fiber 10%
• Construction Industry 10%
• Flexural Strength 10%
• Construction Practice 10%
• Cyclic Loading 10%
• Life Cycle Analysis 10%
• Reinforced 10%
• Concrete Elements 10%
• Carbon Fiber Reinforced 10%
• One-part 10%
• Mortar 10%
• Cost-effectiveness 10%
• Fiber Network 10%
• Superior Mechanical Properties 10%
• Long-term Performance 10%
• Uniformly Dispersed 10%
• Self-sensing 10%
• Piezoelectric Properties 10%
• Environmental Benefits 10%
• Drying Shrinkage 10%
• Nucleation Site 10%
• High Viscosity 10%
• Low Percolation Threshold 10%
• Carbon Neutrality 10%
• Carbon Emissions 10%
• Waste of Carbon Fiber 10%
• Alkali-activated Mortar 10%
• Early Compressive Strength 10%
• Self-sensing Concrete 10%
• Sustainable Reuse 10%
• Carbon Fiber Dispersion 10%
• Valuable Insight 10%

Engineering

• Ground Granulated Blast Furnace Slag 100%
• Piezoelectric 33%
• Term Performance 33%
• Environmental Benefit 33%
• Concrete Element 33%
• Drying Shrinkage 33%
• Nucleation Site 33%
• Fiber Dispersion 33%
• Percolation Threshold 33%
• Activated Slag 33%
• Reinforced Material 33%
• Sensing Concrete 33%
• Cyclic Loading 33%
• Life Cycle Analysis 33%
• Compression Strength 33%
• Compressive Strength 33%
• Bending Strength 33%

Material Science

• Cementitious Material 100%
• Carbon Fiber 100%
• Flexural Strength 9%
• Nucleation 9%
• Compressive Strength 9%
• Piezoelectric Property 9%
• Percolation 9%
• Self-Sensing Concrete 9%