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Interfacial strengthening in bio-inspired materials: a review

Dheeraj Gunwant

2024Composite Interfaces20 citationsDOI

Abstract

This article extensively explores various bio-inspired techniques of interfacial strengthening. Bio-inspired composites fabricated by emulating five natural materials: nacre, byssus thread, plant roots, bone, and spider silk have been discussed. A detailed account of the strengthening mechanisms active in these natural materials responsible for improving fiber/matrix adhesion in artificial composites is presented. Dendritic growth on fiber surfaces is crucial in enhancing the mechanical properties via interlocking in root-inspired composites. Micro-waviness, nano-asperity interlocking, shear deformation, and mineral bridge fracture are the main strengthening mechanisms active in the nacre-inspired composites. Byssal threads have exceptional adhesive properties due to the sacrificial bonds, hidden length, and strong metal coordination cross-links. The typical ‘Bouligand’ microstructure of bone has inspired different composite materials with excellent crack deflection and arresting. Spider silk fibers have a highly oriented proteinous structure surrounded by a semi-amorphous matrix. Their skin-core structure provides tensile strength and toughness to these fibers, inspiring various artificial composites. This article explores additive manufacturing and chemical modification as the implementation techniques for bio-inspired strengthening. Applications of bio-inspired composites include biomedical, marine, aerospace, and tissue engineering. Challenges, such as optimal mechanical properties, sustainability, simulation, and integration with Industry 5.0, must be addressed systematically to augment their applicability.

Topics & Concepts

Materials scienceComposite materialNanotechnologyBone Tissue Engineering MaterialsCalcium Carbonate Crystallization and InhibitionSilk-based biomaterials and applications
Interfacial strengthening in bio-inspired materials: a review | Litcius