Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials

The modeling and analysis of the damage and failure of materials and structures is an active and persistent challenge in computational mechanics, materials, and various scientific and industrial fields. This reprint provides an informative and stimulating forum to enhance academic communications on...

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collection Directory of Open Access Books
description The modeling and analysis of the damage and failure of materials and structures is an active and persistent challenge in computational mechanics, materials, and various scientific and industrial fields. This reprint provides an informative and stimulating forum to enhance academic communications on this challenging topic, focusing on the development and applications of computational theories, numerical and experimental methods, models, and algorithms for modeling and analyzing the damage and failure of concrete-like, brittle, and quasi-brittle materials and structures.
format Online
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institution Directory of Open Access Books
language eng
publishDate 2024
publishDateRange 2024
publishDateSort 2024
publisher MDPI - Multidisciplinary Digital Publishing Institute
publisherStr MDPI - Multidisciplinary Digital Publishing Institute
record_format ojs
spelling doab-20.500.12854ir-1378492024-05-14T14:42:47Z Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials Huang, Dan Liu, Lisheng Cheng, Zhanqi Wu, Liwei bond–slip relationship engineering cementitious composites finite element model high-strength stainless steel wire mesh ca-alginate protonation theory cement-based materials internal curing self-healing engineered cementitious composites damage constitutive model stress–strain relationship tensile performance monotonic uniaxial tensile test environment-friendship mortar seawater and sea sand strength and damage manufactured sand UHPC curing methods mechanical properties bond strength precast utility tunnel concrete damage spiral stirrup finite element ductility planar structures vibration mode modal strain energy relatively weak areas quantification and visualization bond-based peridynamics theory quasi-brittle materials thermo-mechanical coupling crack propagation concrete sleeper damage form damage mechanisms longitudinal crack transversal crack limit state method cement mortar slab impact cracking CDEM hammerhead shape impact velocity prefabricated SSPCM granary wall green grain storage heat transfer characteristics thermal conductivity peridynamics traction-associated peridynamic motion equation traction boundary condition bond-based constitutive model improved micropolar model RC shear walls numerical simulation impact failure impact response of ceramics zero-energy mode kinetic energy bond-breaking criterion concrete hysteretic behavior energy dissipation cyclic loading smeared crack model dynamic behavior high-strength steel-fiber-reinforced concrete rapid hardening compressive performance strain rate curing age foundry wastes ceramic mold shells paraffin wax eco-friendly mortars freeze–thaw performance thema EDItEUR::P Mathematics and Science::PS Biology, life sciences The modeling and analysis of the damage and failure of materials and structures is an active and persistent challenge in computational mechanics, materials, and various scientific and industrial fields. This reprint provides an informative and stimulating forum to enhance academic communications on this challenging topic, focusing on the development and applications of computational theories, numerical and experimental methods, models, and algorithms for modeling and analyzing the damage and failure of concrete-like, brittle, and quasi-brittle materials and structures. 2024-05-14T14:42:41Z 2024-05-14T14:42:41Z 2024 book ONIX_20240514_9783725804948_445 9783725804948 9783725804931 https://directory.doabooks.org/handle/20.500.12854/137849 eng application/octet-stream Attribution-NonCommercial-NoDerivatives 4.0 International https://mdpi.com/books/pdfview/book/9088 https://mdpi.com/books/pdfview/book/9088 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-7258-0493-1 10.3390/books978-3-7258-0493-1 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783725804948 9783725804931 330 open access
spellingShingle bond–slip relationship
engineering cementitious composites
finite element model
high-strength stainless steel wire mesh
ca-alginate
protonation theory
cement-based materials
internal curing
self-healing
engineered cementitious composites
damage constitutive model
stress–strain relationship
tensile performance
monotonic uniaxial tensile test
environment-friendship
mortar
seawater and sea sand
strength and damage
manufactured sand
UHPC
curing methods
mechanical properties
bond strength
precast utility tunnel
concrete damage
spiral stirrup
finite element
ductility
planar structures
vibration mode
modal strain energy
relatively weak areas
quantification and visualization
bond-based peridynamics theory
quasi-brittle materials
thermo-mechanical coupling
crack propagation
concrete sleeper
damage form
damage mechanisms
longitudinal crack
transversal crack
limit state method
cement mortar slab
impact cracking
CDEM
hammerhead shape
impact velocity
prefabricated SSPCM granary wall
green grain storage
heat transfer characteristics
thermal conductivity
peridynamics
traction-associated peridynamic motion equation
traction boundary condition
bond-based constitutive model
improved micropolar model
RC shear walls
numerical simulation
impact failure
impact response of ceramics
zero-energy mode
kinetic energy
bond-breaking criterion
concrete
hysteretic behavior
energy dissipation
cyclic loading
smeared crack model
dynamic behavior
high-strength steel-fiber-reinforced concrete
rapid hardening
compressive performance
strain rate
curing age
foundry wastes
ceramic mold shells
paraffin wax
eco-friendly mortars
freeze–thaw performance
thema EDItEUR::P Mathematics and Science::PS Biology, life sciences
Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title_full Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title_fullStr Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title_full_unstemmed Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title_short Modeling and Analysis of Damage and Failure of Concrete-Like, Brittle and Quasi-brittle Materials
title_sort modeling and analysis of damage and failure of concrete like brittle and quasi brittle materials
topic bond–slip relationship
engineering cementitious composites
finite element model
high-strength stainless steel wire mesh
ca-alginate
protonation theory
cement-based materials
internal curing
self-healing
engineered cementitious composites
damage constitutive model
stress–strain relationship
tensile performance
monotonic uniaxial tensile test
environment-friendship
mortar
seawater and sea sand
strength and damage
manufactured sand
UHPC
curing methods
mechanical properties
bond strength
precast utility tunnel
concrete damage
spiral stirrup
finite element
ductility
planar structures
vibration mode
modal strain energy
relatively weak areas
quantification and visualization
bond-based peridynamics theory
quasi-brittle materials
thermo-mechanical coupling
crack propagation
concrete sleeper
damage form
damage mechanisms
longitudinal crack
transversal crack
limit state method
cement mortar slab
impact cracking
CDEM
hammerhead shape
impact velocity
prefabricated SSPCM granary wall
green grain storage
heat transfer characteristics
thermal conductivity
peridynamics
traction-associated peridynamic motion equation
traction boundary condition
bond-based constitutive model
improved micropolar model
RC shear walls
numerical simulation
impact failure
impact response of ceramics
zero-energy mode
kinetic energy
bond-breaking criterion
concrete
hysteretic behavior
energy dissipation
cyclic loading
smeared crack model
dynamic behavior
high-strength steel-fiber-reinforced concrete
rapid hardening
compressive performance
strain rate
curing age
foundry wastes
ceramic mold shells
paraffin wax
eco-friendly mortars
freeze–thaw performance
thema EDItEUR::P Mathematics and Science::PS Biology, life sciences
topic_facet bond–slip relationship
engineering cementitious composites
finite element model
high-strength stainless steel wire mesh
ca-alginate
protonation theory
cement-based materials
internal curing
self-healing
engineered cementitious composites
damage constitutive model
stress–strain relationship
tensile performance
monotonic uniaxial tensile test
environment-friendship
mortar
seawater and sea sand
strength and damage
manufactured sand
UHPC
curing methods
mechanical properties
bond strength
precast utility tunnel
concrete damage
spiral stirrup
finite element
ductility
planar structures
vibration mode
modal strain energy
relatively weak areas
quantification and visualization
bond-based peridynamics theory
quasi-brittle materials
thermo-mechanical coupling
crack propagation
concrete sleeper
damage form
damage mechanisms
longitudinal crack
transversal crack
limit state method
cement mortar slab
impact cracking
CDEM
hammerhead shape
impact velocity
prefabricated SSPCM granary wall
green grain storage
heat transfer characteristics
thermal conductivity
peridynamics
traction-associated peridynamic motion equation
traction boundary condition
bond-based constitutive model
improved micropolar model
RC shear walls
numerical simulation
impact failure
impact response of ceramics
zero-energy mode
kinetic energy
bond-breaking criterion
concrete
hysteretic behavior
energy dissipation
cyclic loading
smeared crack model
dynamic behavior
high-strength steel-fiber-reinforced concrete
rapid hardening
compressive performance
strain rate
curing age
foundry wastes
ceramic mold shells
paraffin wax
eco-friendly mortars
freeze–thaw performance
thema EDItEUR::P Mathematics and Science::PS Biology, life sciences
url ONIX_20240514_9783725804948_445