Learning from nature: Use material architecture to break the performance tradeoffs

Learning from nature: Use material architecture to break the performance tradeoffs

In material science, the enhancement of a specific material performance is often accompanied by undermining another material property, notoriously known as the performance tradeoffs, such as that between strength and toughness, stiffness and energy dissipation, and flexibility and fast response. Fre...

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Bibliographic Details
Published in:Materials & design Vol. 168; p. 107650
Main Authors: Jia, Zian, Yu, Yang, Wang, Lifeng
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-04-2019
Elsevier
Subjects:
Architected materials
Biomimetics
Hierarchical materials
Performance tradeoffs
Structure-property relationships
Hierarchical materials
Performance tradeoffs
Biomimetics
Architected materials
Structure-property relationships
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Summary:In material science, the enhancement of a specific material performance is often accompanied by undermining another material property, notoriously known as the performance tradeoffs, such as that between strength and toughness, stiffness and energy dissipation, and flexibility and fast response. Free combinations of material properties that go beyond these performance tradeoffs are highly desirable in areas as diverse as civil engineering, soft robotics, armor designs, and reconfigurable metamaterials. Learning from nature, we 3D print architected materials with bio-inspired microstructures that successfully surpass the above performance tradeoffs. The integration of microstructural elements on multiple length scales (hierarchical designs) and on one specific length scale (hybrid designs) are further discussed and compared. Through experimental and theoretical analysis, we reveal that the performance enhancements stem from the material architecture's significant manipulation over the deformation field, crack location, and crack pattern. This study on the relationship between material microstructure and material performance will aid architected material design with ideal combinations of mechanical properties. [Display omitted] •“Strong and tough”, “strong and compliant”, “stiff and dissipative”, and “flexible and responsive” architected materials are designed, breaking the performance tradeoffs in bulk materials.•The dynamic performances of five bioinspired microstructures are compared.•Quantitative material indices are proposed to characterize the material’s overall performance.•Combining hierarchical designs with hybrid designs results in better impact resistance.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2019.107650