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Multifunctional, Sustainable, and Biological Non-Ureolytic Self-Healing Systems for Cement-Based Materials

Mohammad Fahimizadeh, Pooria Pasbakhsh, Lee Sui Mae, Joash Ban Lee Tan, R.K. Singh Raman

2022Engineering67 citationsDOIOpen Access PDF

Abstract

Microbially induced calcium carbonate (CaCO3) precipitation (MICP) has been investigated as a sustainable alternative to conventional concrete remediation methods for improving the mechanical properties and durability of concrete structures. To date, urea-dependent MICP is the most widely employed MICP pathway in biological self-healing concrete research as its use has resulted in efficient CaCO3 precipitation rates. NH3 is a byproduct of ureolysis, and can be hazardous to cementitious structures and the health of various species. Accordingly, non-ureolytic bacterial concrete self-healing systems have been developed as eco-friendly alternatives to urea-dependent self-healing systems. Non-ureolytic pathways can improve the physical properties of concrete samples and incorporate the use of waste materials; they have the potential to be cost-effective and sustainable. Moreover, they can be applied in terrestrial and marine environments. To date, research on non-ureolytic concrete self-healing systems has been scarce compared to that on ureolytic systems. This article discusses the advances and challenges in non-ureolytic bacterial concrete self-healing studies and highlights the directions for future research.

Topics & Concepts

CementitiousHazardous wasteSelf-healingDurabilityEnvironmental remediationCementEnvironmental scienceMaterials scienceWaste managementEnvironmental chemistryChemistryComposite materialEngineeringContaminationEcologyPathologyAlternative medicineMedicineBiologyMicrobial Applications in Construction MaterialsCorrosion Behavior and InhibitionConcrete and Cement Materials Research
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