Heterostructured mechanical metamaterials inspired by the shell of Strombus gigas

Juzheng Chen; Hao Wu; Jingzhuo Zhou; Ziyong Li; Ke Duan; Ruihan Xu; Tianyi Jiang; Hongyuan Jiang; Rong Fan; Roberto Ballarini; Yang Lu

doi:10.1016/j.jmps.2024.105658

Heterostructured mechanical metamaterials inspired by the shell of Strombus gigas

Juzheng Chen (Co-first Author), Hao Wu (Co-first Author), Jingzhuo Zhou, Ziyong Li, Ke Duan, Ruihan Xu, Tianyi Jiang, Hongyuan Jiang, Rong Fan^*, Roberto Ballarini^*, Yang Lu^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

16 Citations (Scopus)

Abstract

Despite being highly mineralized, the shells of molluscs exhibit superior strength and toughness because their architectural designs control the evolution of cracks and other types of localized deformation such as shear bands. The crossed-lamellar design of the shell of Strombus gigas, whose hierarchy consists of four distinct lamellar-shaped features assembled in a three-dimensional arrangement, represents the toughest of all seashells. A mechanical metamaterial that adapts the geometrical design of this queen conch is anticipated to circumvent the typical trade-offs between strength-ductility and strength-density. Inspired by the three-dimensional hierarchical and interactive architecture of the crossed-lamellar microstructure, we instruct the design of bio-inspired metamaterials that mitigate failure from the extension of a single shear band and instead develop numerous smaller bands confined within the individual plank-like zones introduced in their layered geometric design. The measured strength properties of these materials are found to increase in inverse proportion to the square root of the thickness of the layers in the hierarchy as a result of progressive deformation enabled by cross-layer interactions. The results provide a new perspective on the design of strong and tough mechanical metamaterials.

© 2024 Elsevier Ltd. All rights reserved.

Original language	English
Article number	105658
Journal	Journal of the Mechanics and Physics of Solids
Volume	188
Online published	28 Apr 2024
DOIs	https://doi.org/10.1016/j.jmps.2024.105658
Publication status	Published - Jul 2024

Funding

This work is financially supported by the Research Grants Council (RGC) Collaborative Research Fund (CRF) project C7074-23GF, Science and Technology Department of Sichuan Province (No. 2022YFSY0001), PRP/054/22FX from Innovation and Technology Commission (ITC), and the Thomas and Laura Hsu Professorship at the University of Houston.

Research Keywords

3D printing
Bio-inspired architecture
Heterostructured
Hierarchical structure
Mechanical metamaterials

RGC Funding Information

RGC-funded

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10.1016/j.jmps.2024.105658

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abstract = "Despite being highly mineralized, the shells of molluscs exhibit superior strength and toughness because their architectural designs control the evolution of cracks and other types of localized deformation such as shear bands. The crossed-lamellar design of the shell of Strombus gigas, whose hierarchy consists of four distinct lamellar-shaped features assembled in a three-dimensional arrangement, represents the toughest of all seashells. A mechanical metamaterial that adapts the geometrical design of this queen conch is anticipated to circumvent the typical trade-offs between strength-ductility and strength-density. Inspired by the three-dimensional hierarchical and interactive architecture of the crossed-lamellar microstructure, we instruct the design of bio-inspired metamaterials that mitigate failure from the extension of a single shear band and instead develop numerous smaller bands confined within the individual plank-like zones introduced in their layered geometric design. The measured strength properties of these materials are found to increase in inverse proportion to the square root of the thickness of the layers in the hierarchy as a result of progressive deformation enabled by cross-layer interactions. The results provide a new perspective on the design of strong and tough mechanical metamaterials.{\textcopyright} 2024 Elsevier Ltd. All rights reserved. ",

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AU - Chen, Juzheng

AU - Wu, Hao

AU - Zhou, Jingzhuo

AU - Li, Ziyong

AU - Duan, Ke

AU - Xu, Ruihan

AU - Jiang, Tianyi

AU - Jiang, Hongyuan

AU - Fan, Rong

AU - Ballarini, Roberto

AU - Lu, Yang

PY - 2024/7

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N2 - Despite being highly mineralized, the shells of molluscs exhibit superior strength and toughness because their architectural designs control the evolution of cracks and other types of localized deformation such as shear bands. The crossed-lamellar design of the shell of Strombus gigas, whose hierarchy consists of four distinct lamellar-shaped features assembled in a three-dimensional arrangement, represents the toughest of all seashells. A mechanical metamaterial that adapts the geometrical design of this queen conch is anticipated to circumvent the typical trade-offs between strength-ductility and strength-density. Inspired by the three-dimensional hierarchical and interactive architecture of the crossed-lamellar microstructure, we instruct the design of bio-inspired metamaterials that mitigate failure from the extension of a single shear band and instead develop numerous smaller bands confined within the individual plank-like zones introduced in their layered geometric design. The measured strength properties of these materials are found to increase in inverse proportion to the square root of the thickness of the layers in the hierarchy as a result of progressive deformation enabled by cross-layer interactions. The results provide a new perspective on the design of strong and tough mechanical metamaterials.© 2024 Elsevier Ltd. All rights reserved.

AB - Despite being highly mineralized, the shells of molluscs exhibit superior strength and toughness because their architectural designs control the evolution of cracks and other types of localized deformation such as shear bands. The crossed-lamellar design of the shell of Strombus gigas, whose hierarchy consists of four distinct lamellar-shaped features assembled in a three-dimensional arrangement, represents the toughest of all seashells. A mechanical metamaterial that adapts the geometrical design of this queen conch is anticipated to circumvent the typical trade-offs between strength-ductility and strength-density. Inspired by the three-dimensional hierarchical and interactive architecture of the crossed-lamellar microstructure, we instruct the design of bio-inspired metamaterials that mitigate failure from the extension of a single shear band and instead develop numerous smaller bands confined within the individual plank-like zones introduced in their layered geometric design. The measured strength properties of these materials are found to increase in inverse proportion to the square root of the thickness of the layers in the hierarchy as a result of progressive deformation enabled by cross-layer interactions. The results provide a new perspective on the design of strong and tough mechanical metamaterials.© 2024 Elsevier Ltd. All rights reserved.

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KW - Bio-inspired architecture

KW - Heterostructured

KW - Hierarchical structure

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Heterostructured mechanical metamaterials inspired by the shell of Strombus gigas

Abstract

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Research Keywords

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ITF: Development of Scalable Ultra-Strength Bamboo Materials with Zero Toxic Adhesive for Bulk Production and Industrial Applications

One-Photon 3D-Printed Sub-micron Fused Silica Glass with Its Applications in Metamaterials and Devices

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Heterostructured mechanical metamaterials inspired by the shell of Strombus gigas

Abstract

Funding

Research Keywords

RGC Funding Information

Access Output

Other Access Options

Permanent Link

Other Files and Links

Fingerprint

Projects

ITF: Development of Scalable Ultra-Strength Bamboo Materials with Zero Toxic Adhesive for Bulk Production and Industrial Applications

Student theses

One-Photon 3D-Printed Sub-micron Fused Silica Glass with Its Applications in Metamaterials and Devices

Cite this