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Abstract

Triboluminescent materials are promising in the field of structural health monitoring for real-time crack detection and related damage assessment. This study presents a simple, but novel, image processing protocol to detect and quantify luminescence from crack formation in cement-based matrices. Mortar cubes of 2″× 2″ (5.1 cm × 5.1 cm) were loaded in compression with an external coating of manganese-doped zinc sulfide (ZnS:Mn) triboluminescent material. The concentration of triboluminescent material and rate of loading were varied to evaluate luminescence response. A digital single lens reflex camera was employed to capture luminescence from the resulting cracks, which formed and propagated during failure. The images were then analyzed with an image processor, and total luminescence/pixel along the cracks was quantified. Results show that overall luminescence increases with the increase in triboluminescent concentration as well as with the rate of loading. This article presents a novel method that can be applied to monitor crack formation in cement-based materials, providing reliable accuracy in luminescence quantification.

Keywords

Triboluminescence manganese-doped zinc sulfide cement-based materials distributed sensing structural health monitoring

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Triboluminescence for distributed damage assessment in cement-based materials

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