Outstanding Strengthening and Toughening Behavior of 3D‐Printed Fiber‐Reinforced Composites Designed by Biomimetic Interfacial Heterogeneity

3D printing of fiber‐reinforced composites is expected to be the forefront technology for the next‐generation high‐strength, high‐toughness, and lightweight structural materials. The intrinsic architecture of 3D‐printed composites closely represents biomimetic micro/macrofibril‐like hierarchical str...

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Bibliographic Details
Published in:Advanced science 2022-01, Vol.9 (3), p.e2103561-n/a
Main Authors: Yu, Siwon, Hwang, Yun Hyeong, Lee, Kang Taek, Kim, Sang Ouk, Hwang, Jun Yeon, Hong, Soon Hyung
Format: Article
Language:English
Subjects:
3-D printers
3D printing
Bamboo
Biomimetics - methods
composites
fiber alignment
hierarchical structures
interfacial heterogeneity
Materials Testing - methods
Microstructure
Polymers
Printing, Three-Dimensional
Shear strength
Stress, Mechanical
Surface Properties
Tensile Strength
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Summary:3D printing of fiber‐reinforced composites is expected to be the forefront technology for the next‐generation high‐strength, high‐toughness, and lightweight structural materials. The intrinsic architecture of 3D‐printed composites closely represents biomimetic micro/macrofibril‐like hierarchical structure composed of intermediate filament assembly among the micron‐sized reinforcing fibers, and thus contributes to a novel mechanism to simultaneously improve mechanical properties and structural features. Notably, it is found that an interfacial heterogeneity between numerous inner interfaces in the hierarchical structure enables an exceptional increase in the toughness of composites. The strong interfacial adhesion between the fibers and matrix, with accompanying the inherently weak interfacial adhesion between intermediate filaments and the resultant interfacial voids, provide a close representation of the toughness behavior of natural architectures relying on the localized heterogeneity. Given the critical embedment length of fiber reinforcement, extraordinary improvement has been attained not only in the strength but also in toughness taking advantage of the synergy effect from the aforementioned nature‐inspired features. Indeed, the addition of a small amount of short fiber to the brittle bio‐filaments results in a noticeable increase of more than 200% in the tensile strength and modulus with further elongation increment. This article highlights the inherent structural hierarchy of 3D‐printed composites and the relevant sophisticated mechanism for anomalous mechanical reinforcement. Here, the authors present that the intrinsic architecture of 3D‐printed composites closely represents biomimetic hierarchical structure composed of intermediate filament assembly among the reinforcing fibers, and thus contribute to a novel mechanism to simultaneously improve mechanical properties and structural features. Notably, the authors find that an interfacial heterogeneity between numerous inner interfaces in the hierarchical structure enables an exceptional increase in the toughness of composites.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202103561