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Abstract
The increasing demands of this modern infrastructure require greater structural performance and long-term sustainability while being cost-effective. For a long time, the quest for such construction materials required durable, intelligent, and cost-effective construction materials. The traditional cementitious materials are very common; however, they have some innate drawbacks: they crack rather easily, cannot self-heal, and lack some damage-monitoring mechanisms for its real-time assessment. Current solutions for structural health monitoring involve extrinsic sensors and wiring that are invasive and costly and do not provide integrated self-healing and damage detection predictivity. This research introduces the work on multi-functional carbon nanotube (CNT) infused smart cement capable of presenting enhanced mechanical performances, in situ damage sensing, and autonomous self-healing capabilities. Key methods used include: 1) chemical functionalization of CNT for better dispersion, bonding, and conductivity, which improves mechanical strength by 30% and electrical conductivity 10-fold; 2) CNT catalyzing microencapsulated self-healing system: more than 85% crack closure efficiency for cracks up to 0.5 mm; 3) three-dimensional printing with CNT infused cement, enabling the creation of complex geometries with embedded sensors, porosity control, and 20% greater structural integrity; 4) wireless damage monitoring using CNT-based antennas for crack detection below 0.1 mm and signal transmission over 50 m; and 5) artificial intelligence (AI)-enhanced predictive maintenance, achieving a prediction accuracy of 95%–98% in crack propagation and reducing maintenance costs by 30%. This novel integration of functionalized CNT, self-healing agents, wireless sensing, and AI-driven analytics simultaneously strengthens structural integrity while permitting sustainable, non-invasive, and scalable monitoring. What these results indicate is enhanced performance, cost-effectiveness, and longevity, making the technology transformative for the next generations of construction materials.
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Keywords
smart cement
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carbon nanotubes
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structural monitoring
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self-healing concrete
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predictive maintenance modeling
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Vikrant S. VAIRAGADE.
Artificial intelligence-driven predictive modeling of multi-functional carbon nanotube infused smart cement for structural reinforcement and real-time damage sensing.
Front. Struct. Civ. Eng., 2025, 19(9): 1403-1417 DOI:10.1007/s11709-025-1219-y
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