INIS
carbon
100%
strain hardening
100%
environment
100%
fibers
61%
matrices
42%
design
28%
fracture properties
28%
pva
23%
slags
23%
adhesion
19%
chemical bonds
19%
interfaces
19%
comparative evaluations
19%
performance
19%
fly ash
19%
gels
14%
mixtures
14%
by-products
14%
chemistry
9%
zones
9%
composite materials
9%
bonding
9%
energy
9%
cracking
9%
microstructure
9%
environmental impacts
9%
interactions
9%
ductility
9%
construction
9%
engineers
9%
solutions
9%
mechanical properties
9%
emission
4%
increasing
4%
durability
4%
carbon footprint
4%
surfaces
4%
electrostatics
4%
cements
4%
reduction
4%
global warming
4%
simulation
4%
evaluation
4%
economy
4%
life cycle assessment
4%
slip
4%
resources
4%
greenhouse gases
4%
recommendations
4%
hardening
4%
sustainability
4%
molecules
4%
volume
4%
industrial wastes
4%
errors
4%
portland cement
4%
chemical composition
4%
precursor
4%
binders
4%
van der waals forces
4%
capillaries
4%
solids
4%
compression strength
4%
length
4%
modeling
4%
cracks
4%
fractures
4%
porosity
4%
Material Science
Work Hardening
100%
Composite Material
100%
Micromechanics
100%
Geopolymers
68%
Fiber
54%
Materials
40%
Chemical Bonding
18%
Adhesion
18%
Mixture
13%
Gel
13%
Byproducts
13%
Microstructure
9%
Building Material
9%
Ductility
9%
Interface Property
9%
Fiber-Reinforced Composite
4%
Cement
4%
Portland Cement
4%
Gas Emission
4%
Binder
4%
Concrete
4%
Greenhouse Gas
4%
Crack Bridging
4%
Compressive Strength
4%
Porosity
4%
Solid
4%
Surface
4%
Durability
4%
Electrostatic Interaction
4%
Keyphrases
Environmentally Friendly Construction
5%
Fracture Interface
5%
Solid Precursor
5%
Engineering
Portland Cement Binder
4%