Insights into the effect of high temperature on the shear behavior of the calcium silicate hydrate by reactive molecular dynamics simulations

Zhang, Yao; Zhang, Shaoqi; Chen, Qing; Shen, Yi; Ju, J. W.; Bauchy, Mathieu

doi:10.1177/10567895221093395

Cited by 10 publications

(2 citation statements)

References 60 publications

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“…Elastic modulus is the key to the fireproof design for structures with fire risk, and it is the essential parameter for evaluating the degree of thermal damage to structures after fires (Zhang et al., 2021). Establishing the relationship between the elastic properties and compositions of cementitious composites is effective to predict the performance at high temperatures and optimize the fire-resistant design of cementitious composites (Zhang et al., 2022). The degradation of elastic properties at high temperatures is mainly attributed to two aspects: the deterioration of mechanical properties of the phase compositions in the cementitious composites and lower stiffness phases generated from phase transformations.…”

Section: Introductionmentioning

confidence: 99%

Multiscale prediction of thermal damage for hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures

Cao,

Liu,

et al. 2024

International Journal of Damage Mechanics

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Thermal damage assessment of cementitious composites is essential for evaluating post-fire health conditions of the engineering structures, as well as the basis for reinforcement and repair after fires. Fibers and fly ash are widely used in cementitious composites due to their excellent properties. However, quantifying and predicting the thermal damage of hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures is still inexplicit. Hence, this study aims to realize multiscale prediction of thermal damage for hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures. First, the volumes of the phase compositions during hydration and dehydration are calculated by the hydration of cement and fly ash and the dehydration of hydration products. Then, a multiscale model is established to predict the thermal damage of hybrid fibers reinforced cementitious composites and verified by the experimental data. At last, the temperature field of tunnel lining structure in fires is obtained by numerical modeling and employing it to predict thermal damage at different thicknesses and moments. Results show that the heating rate determines the dehydration degree of hydration products and the volumes of the phase composites at high temperatures. The proposed multiscale model can reflect the thermal microcracking of cement paste, the interfacial thermal damage between aggregates and the cement paste, and the deterioration of elastic modulus of fibers. After three hours of exposure to fires, serious damage appears at the surface and the thickness of 2 cm and 5 cm of the lining, while there is nearly no damage at a thickness of 30 cm or more.

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Section: Introductionmentioning

confidence: 99%

Multiscale prediction of thermal damage for hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures

Cao,

Liu,

et al. 2024

International Journal of Damage Mechanics

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“…There is no doubt that the research on resilience at the material level will become a research hotspot in the field of materials. Concrete structures built with self-healing materials have self-healing properties after disaster damage, and research on this aspect can improve the safety and sustainability of the entire life cycle of underground structures (Chen et al., 2021; Ivica et al., 2022; Tian et al., 2019; Voyiadjis et al., 2020; Wei et al., 2023; Zhang et al., 2022; Zhu et al., 2021). Based on different healing methods, many healing materials have been proposed by different scholars, such as the microencapsulated self-healing concrete (Andrushia et al., 2020a, 2020b; Jahadi et al., 2023; Zhou et al., 2020; Zhuang et al., 2021), the UHPC (Fang et al., 2022; Luo et al., 2019; Zhu et al., 2022), the slurry infiltrated fiber concrete (Zhou et al., 2023), the lightweight aggregate concrete (Xiong et al., 2019, 2022a, 2022b), the calcined wollastonite powder (Zheng et al., 2021), the ECC (Zhou et al., 2020) and the bacteria-based concrete (Zhuang and Zhou, 2019).…”

Section: Introductionmentioning

confidence: 99%

A resilience assessment framework for microencapsulated self-healing cementitious composites based on a micromechanical damage-healing model

Han,

Ju,

Zhang

et al. 2023

International Journal of Damage Mechanics

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In this paper, a resilience assessment framework for microencapsulated self-healing cementitious composites is proposed based on a micromechanical damage-healing model. A 3D micromechanical analytical model is constructed to analyze the performance evolution during the damage-healing process of self-healing concrete. The resilience assessment of microencapsulated self-healing concrete is defined by virtue of the residual stiffness, self-healing effect on stiffness and damage cumulative on stiffness, which corresponds to three main features of resilience; namely, the robustness, recoverability and adaptability. The assessment results indicate that the release of healing agents within microcapsules and healing process of extended microcracks allows the microencapsulated self-healing concrete to have higher resilience than conventional concrete. Moreover, a parameter sensitivity analysis is conducted to investigate the influence of the healing efficiency, the applied initial damage and the fracture toughness of the repaired microcrack on resilience of microencapsulated self-healing concrete. The results indicate that higher healing efficiency and applied initial damage leads to high resilience, and fracture toughness of the repaired microcrack makes less difference to the results. The findings of this paper lay a theoretical foundation for the resilience design of self-healing material layer of underground structures.

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Insights into the thermal effect on the fracture toughness of calcium silicate hydrate grains: A reactive molecular dynamics study

Zhang

Zhang²,

Jiang³

et al. 2022

Cement and Concrete Composites

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Insights into the effect of high temperature on the shear behavior of the calcium silicate hydrate by reactive molecular dynamics simulations

Cited by 10 publications

References 60 publications

Multiscale prediction of thermal damage for hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures

Multiscale prediction of thermal damage for hybrid fibers reinforced cementitious composites blended with fly ash at high temperatures

A resilience assessment framework for microencapsulated self-healing cementitious composites based on a micromechanical damage-healing model

Insights into the thermal effect on the fracture toughness of calcium silicate hydrate grains: A reactive molecular dynamics study

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