Sustainable strategy of eggshell waste usage in cementitious composites: An integral testing and computational study for compressive behavior in aggressive environment

•The influence of eggshell powder on 90-day compressive strength cement mortar was explored.•The response of cement mortar modified with treated eggshell powder under an acidic environment was studied.•The incorporation of eggshell powder improved the resistance of cement mortar to acid attack.•The...

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Bibliographic Details
Published in:Construction & building materials 2023-07, Vol.386, p.131536, Article 131536
Main Authors: Wang, Nanlan, Xia, Zhengjun, Amin, Muhammad Nasir, Ahmad, Waqas, Khan, Kaffayatullah, Althoey, Fadi, Alabduljabbar, Hisham
Format: Article
Language:English
Subjects:
Acid attack
Cementitious composites
Compressive strength
Eggshell powder
Sustainable material
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Summary:•The influence of eggshell powder on 90-day compressive strength cement mortar was explored.•The response of cement mortar modified with treated eggshell powder under an acidic environment was studied.•The incorporation of eggshell powder improved the resistance of cement mortar to acid attack.•The developed machine learning models exhibited good agreement with the test results. The effectiveness of cementitious composites in an aggressive environment is the primary issue since their performance deteriorates when exposed to harmful elements. Also, to promote sustainable building materials, waste materials are gaining popularity. This work employed testing followed by machine learning (ML) modeling to study the impact of eggshell powder (ESP) in cement mortar exposed to an acidic environment. The ESP was used to partially replace cement and sand, and the samples were subjected to a 5% H2SO4 solution. The dataset obtained through experimentation was utilized to construct ML-based predictive models for the reduction in compressive strength (CS) of cement mortar. According to the test results, the integration of ESP controlled the loss of cement mortar when used at lower substitutional levels. The lowest reduction in CS was seen when ESP was used as a cement substitute of 5%, which was up to 7.71% lower, and as a sand substitute of 7.5%, which was up to 7.03% lower than the same mix placed in plain water as a reference. Furthermore, the developed ML models exhibited a satisfactory level of concurrence with the experimental findings, thereby indicating their potential applicability in assessing the CS reduction percentage in cement mortar that incorporates ESP subsequent to an acid attack.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2023.131536