Curto, Marco, Dowsett, Jack, Kao, Alexander, Tozzi, Gianluca and Barber, Asa (2025) Multi-material 3D printed composites inspired by nacre: a hard/soft mechanical interplay. Scientific Reports, 15:6728. ISSN 2045-2322 (Online) (doi:10.1038/s41598-025-91080-2)

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Abstract

Structural materials are used extensively in nature where mechanical function is required. These structures are composites consisting of soft and, in some cases, hard phases precisely distributed over different length scales. Bio-inspiration aims at producing materials with structure, design and/or mechanical properties adopted from biological tissues. To reproduce complex structures found in nature, additive manufacturing (AM) using three-dimensional printing (3DP) is an attractive method to assemble complex topologies with resolutions approaching the micro and nano-composition. Specifically, high-resolution MultiJetPrinting (MJP) 3D printing allows the simultaneous deposition of soft and hard photo curable plastic resins. Nacre is a prevalent example of a complex biological composite material organization that can test the ability of MJP to manufacture a bio-inspired engineering structure, where the organization of materials in nacre is optimized to avoid catastrophic failure. The ability to generate complex 3D organizations required to mimic the structure of nacre by controlled organization of soft and hard materials is achieved here using a generative design approach. Such a generative design is further enhanced by incorporating two differing MJP directions that provide relatively strong and weak interfaces between the soft and hard material phases. Consideration of classical stress transfer theory between at a hard material reinforcement interface was shown to correlate with experimental observations of mechanical performance and failure in 3D printed nacre inspired composites. Thus, the ability to distribute materials with a range of mechanical properties and incorporate further interfacial design is demonstrated. The approach presented is flexible and allows complex bio-inspired composites to be 3D printed that incorporate different interfacial quality through changing printing direction.

Item Type:	Article
Additional Information:	The authors acknowledge support from the University of Portsmouth for XCT imaging and 3D printing.
Uncontrolled Keywords:	bioinspired, additive manufacturing, 3D printing, composites, X-ray tomography, multi-material
Subjects:	N Fine Arts > N Visual arts (General) For photography, see TR Q Science > Q Science (General) T Technology > T Technology (General)
Faculty / School / Research Centre / Research Group:	Faculty of Engineering & Science Faculty of Engineering & Science > School of Engineering (ENG)
Last Modified:	19 Nov 2025 12:18
URI:	https://gala.gre.ac.uk/id/eprint/51675

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