Advances in Cement Composite Materials

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

dam; gallery concrete; strength; fracture parameters; maturity model; cracking risk; ambient temperature; ambient humidity; metakaolin; green concrete; machine learning; compressive strength; hyperparameters; natural fiber; date palm fiber; silica fume; composites; date-palm-fiber-reinforced concrete; mechanical properties; phosphogypsum; calcium sulphoaluminate aluminate cement; gypsum; calcium hydroxide; strength; hydration properties; geopolymer; fly ash; mechanical properties; compressive strength; flexural strength; environmentally friendly materials; sustainable development; green alternative; environmental solutions; UHPC; local materials; curing regimens; workability; mechanical strengths; permeable porosity; hydraulic structure; fully graded; fracture parameters; size effect; fracture extreme theory; recycled brick; recycled granite; cement; recycled aggregate; recycled powder; basalt-fiber-reinforced cemented soil; damage model; Weibull distribution; unconfined compressive strength; self-compacting mortar; self-compacting concrete; superabsorbent polymer; SAP; internal curing; heat of hydration; carbon fiber; aramid fiber; hybrid-fiber-reinforced concrete; mechanical strength; impact loading; split Hopkinson pressure bar; fly ash; calcium aluminate cement; conversion; hydration; performance; composition; fine quartz sand; thermal dilatation; DTA; chemical purity; grain shape; technological properties