Experimental and numerical study on post-fire self-healing concrete for enhanced durability

Experimental and numerical study on post-fire self-healing concrete for enhanced durability

Abstract Fire hazards pose significant risks to civil infrastructure, leading to concrete degradation. This study explores the development of post-fire self-healing concrete incorporating encapsulated or immobilized bacteria to restore structural integrity after fire exposure. Key challenges address...

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Bibliographic Details
Main Authors: Ajitanshu Vedrtnam, Martin T. Palou, Hugo Varela, Dheeraj Gunwant, Kishor Kalauni, Gonzalo Barluenga
Format: Article
Language:English
Published: Nature Portfolio 2025-03-01
Series:Scientific Reports
Subjects:
Finite element modelling
Mechanical characterization
Open fire test
Self-healing concrete
Thermal test
Ultrasonic test
Online Access:https://doi.org/10.1038/s41598-025-94331-4
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Summary:Abstract Fire hazards pose significant risks to civil infrastructure, leading to concrete degradation. This study explores the development of post-fire self-healing concrete incorporating encapsulated or immobilized bacteria to restore structural integrity after fire exposure. Key challenges addressed include protecting bacteria during fire exposure and activating them post-fire. Innovative encapsulation techniques were developed to shield bacteria within concrete samples during fires, enabling their activation afterward to enhance structural strength. A finite element model simulated the time-temperature profile within the concrete and cement-based composites, replicating experimental conditions. Concrete samples underwent customized ISO 834 standard testing for a shorter period, open fire tests, and ultrasonic assessments to evaluate residual properties post-heating. A novel surface treatment was devised to protect embedded bacteria during fire exposure, proving effective in maintaining bacterial viability and enabling post-fire self-healing. A finite element model was employed to simulate the internal temperature profiles and assess the effectiveness of bacterial activation post-fire. The results confirm that the encapsulated bacteria can survive fire exposure and subsequently enhance the concrete’s mechanical properties, marking a significant advance in fire-resistant construction materials. The research establishes critical time-temperature thresholds for the feasibility of post-fire self-healing in concrete, presenting a significant advancement in fire-resistant construction materials.
ISSN:2045-2322

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