Simulating water penetration in cementitious materials using pore structures from mercury intrusion porosimetry

Liquid water penetration is an important factor affecting the lifespan of concrete structures, as it causes various forms of deterioration, such as frost damage and rebar corrosion. Despite its significance, the relationship between pore structure and water penetration remains poorly understood, and...

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Published inCase Studies in Construction Materials Vol. 22; p. e04492
Main Author Sakai, Yuya
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.07.2025
Subjects
Concrete
Damage
Interfacial transition zone
Mercury intrusion porosimetry
Microcrack
Simulation
Tortuosity
Water penetration
Microcrack
Simulation
Tortuosity
Mercury intrusion porosimetry
Water penetration
Concrete
Damage
Interfacial transition zone
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Abstract Liquid water penetration is an important factor affecting the lifespan of concrete structures, as it causes various forms of deterioration, such as frost damage and rebar corrosion. Despite its significance, the relationship between pore structure and water penetration remains poorly understood, and a practical method for estimating the water penetration rate in existing concrete structures has yet to be developed. This study presents a method for estimating water penetration into cementitious materials through a simple numerical calculation based on pore-size distribution, as evaluated by mercury intrusion porosimetry (MIP), under the assumption of a simple cubic lattice. The simulation results generally underestimated the experimental results, likely due to unaccounted factors such as differences in coordination numbers and the presence of gravel. It was found that considering a fixed tortuosity improved the simulation results, achieving quantitative agreement with experimental data, indicating that water permeability can be estimated quantitatively based on MIP results. However, it was found that certain experimental results were independent of porosity, a trend the simulation failed to reproduce. This discrepancy may arise from the substantial role of localised paths, such as interfacial transition zones or microcracks, in water penetration within these samples. As MIP provides only averaged pore structure information, detecting such localised pathways and estimating the water penetration rate in these cases remain subjects for future research.
AbstractList Liquid water penetration is an important factor affecting the lifespan of concrete structures, as it causes various forms of deterioration, such as frost damage and rebar corrosion. Despite its significance, the relationship between pore structure and water penetration remains poorly understood, and a practical method for estimating the water penetration rate in existing concrete structures has yet to be developed. This study presents a method for estimating water penetration into cementitious materials through a simple numerical calculation based on pore-size distribution, as evaluated by mercury intrusion porosimetry (MIP), under the assumption of a simple cubic lattice. The simulation results generally underestimated the experimental results, likely due to unaccounted factors such as differences in coordination numbers and the presence of gravel. It was found that considering a fixed tortuosity improved the simulation results, achieving quantitative agreement with experimental data, indicating that water permeability can be estimated quantitatively based on MIP results. However, it was found that certain experimental results were independent of porosity, a trend the simulation failed to reproduce. This discrepancy may arise from the substantial role of localised paths, such as interfacial transition zones or microcracks, in water penetration within these samples. As MIP provides only averaged pore structure information, detecting such localised pathways and estimating the water penetration rate in these cases remain subjects for future research.
ArticleNumber e04492
Author Sakai, Yuya
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  organization: Institute of Industrial Science, The University of Tokyo, 4-6-1 Be404 Komaba, Meguro, Tokyo 153-8505, Japan
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Keywords Microcrack
Simulation
Tortuosity
Mercury intrusion porosimetry
Water penetration
Concrete
Damage
Interfacial transition zone
Language English
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Snippet Liquid water penetration is an important factor affecting the lifespan of concrete structures, as it causes various forms of deterioration, such as frost...
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SourceType Index Database
Publisher
StartPage e04492
SubjectTerms Concrete
Damage
Interfacial transition zone
Mercury intrusion porosimetry
Microcrack
Simulation
Tortuosity
Water penetration
Title Simulating water penetration in cementitious materials using pore structures from mercury intrusion porosimetry
URI https://dx.doi.org/10.1016/j.cscm.2025.e04492
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