Reprint
Advances in Cement Composite Materials
Edited by
March 2024
256 pages
- ISBN978-3-7258-0714-7 (Hardback)
- ISBN978-3-7258-0713-0 (PDF)
This is a Reprint of the Special Issue Advances in Cement Composite Materials that was published in
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Summary
The aim of the Special Issue entitled "Advances in Cement Composite Materials" was to present current trends and advances in cement composite materials not only based on ordinary Portland cement (OPC) and natural aggregates but also in the use of other materials or raw materials incorporated into the cement matrix.
Format
- Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
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