Research and Development of Modified Building Materials

© 2022 by the authors; CC BY-NC-ND license

single wall carbon nanotubes; surfactant; TritonX-100; mass of specimens; compressive strength; flexural Strength; bulk density; ternary cements; limestone; siliceous fly ash; granulated blast furnace slag; concrete properties; concrete durability; CO₂ emission; detached decorative plasters; injection grout; glass microspheres; reduced density; stability; strength; durability; clay mortars; activating solutions; wetting–drying; freeze–thaw cycles; microstructure; superabsorbent polymer; steel fibers; high-performance fiber reinforced concrete; digital image correlation; autogenous shrinkage; tensile behavior; nano-calcium oxide; nano-silica; self-healing; cement pastes; curing regime; gypsum binder; additives; light-materials; porosity; thermal insulation; cement; hydrated lime; HEMC; mortar; paste; hydration; setting process; ultrasonic technique; cement; graphite; additives; electrical conductivity; self-sensing; multi-walled carbon nanotubes; cement-based materials; flexural strength; compressive strength; electrical resistivity; activation energy; supplementary cementitious materials; packing density; filler effect; high calcium fly ash; ladle furnace slag; limestone filler; foamed geopolymer; reinforcing lightweight concrete; glass fiber composites; concrete; thermal properties; structural properties; composite modified asphalt binder; rheological properties; storage stability; microstructure; amorphous poly alpha olefin; polyphosphoric acid; rheological properties; application properties; water retention; cement; hydrated lime; plaster; cellulose ether; viscosity; self-compacting concrete (SCC); mix proportion design; optimization; experimental verification; the grey relational analysis; hook-end steel fiber; bond performance; pullout test; inclination angle; fiber spacing; pullout load-slip curve