Bioinspired microstructure design simultaneously enhances strain-rate stiffening and toughening of composites
Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review
Author(s)
Related Research Unit(s)
Detail(s)
Original language | English |
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Article number | 110389 |
Journal / Publication | Engineering Fracture Mechanics |
Volume | 309 |
Online published | 11 Aug 2024 |
Publication status | Published - 1 Oct 2024 |
Link(s)
DOI | DOI |
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Document Link | Links
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Link to Scopus | https://www.scopus.com/record/display.uri?eid=2-s2.0-85202051435&origin=recordpage |
Permanent Link | https://scholars.cityu.edu.hk/en/publications/publication(e01e71f4-b58d-4ab2-94bb-a5fd13c26f7d).html |
Abstract
Keratinous biological materials, such as baleen, pangolin scales, and human hair, have similar constituent materials. However, their strain-rate dependent mechanical properties vary due to differences in their microstructures. Inspired by the microstructures observed in baleen, here we present novel microstructural designs of three types of lamellar-tubular fibers, namely the lamellar-tubular fiber (LTF), mineralized lamellar-tubular fiber (MLTF) and hollow mineralized-lamellar-tubular fiber (HMLTF). We systematically investigated their strain-rate dependent mechanical behaviors with comparison to the conventional cylinder-fiber (CF) reinforced composites. Through the finite element analysis (FEA), we found that the baleen-inspired composites have superior strain-rate stiffening and toughening effects than the conventional fiber reinforced composite. Rate-dependent constitutive models decoupling elastic and inelastic regimes were constructed for these bioinspired composites. Based on the FEA results, three constitutive parameters were obtained to quantitatively characterize the rate-dependent mechanical behaviors of these composites, especially the microstructure-induced difference. Furthermore, our study found that the baleen-inspired tubular microstructure improves stiffness and strain-rate stiffening through raising the stress levels of all phases and improves toughness and strain-rate toughening through enlarging the deformation in the inelastic region. This novel bioinspired design is hopeful to pave ways for the development of advanced composites with simultaneously enhanced strain-rate stiffening and toughening. © 2024 Elsevier Ltd.
Research Area(s)
- Bioinspired microstructure design, Composite material, Constitutive model, Finite element analysis, Strain-rate dependent mechanical behavior
Citation Format(s)
In: Engineering Fracture Mechanics, Vol. 309, 110389, 01.10.2024.
Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review