Thermal Expansion of Hybrid Chiral Mechanical Metamaterial with Patterned Bi‐Strips

Liu, Siyao; Li, Yaning

doi:10.1002/adem.202300478

Cited by 3 publications

(1 citation statement)

References 51 publications

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“…Metamaterials are categorized based on the specific properties they are engineered to manipulate. These categories include mechanical metamaterials [2], thermal metamaterials [3,4], acoustic metamaterials [5], and more.…”

Section: Introductionmentioning

confidence: 99%

Martensitic Phase-Transforming Metamaterial: Concept and Model

Kanegae,

Okugawa,

Koizumi

2023

Materials

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We successfully developed a mechanical metamaterial that displays martensitic transformation for the first time. This metamaterial has a bistable structure capable of transitioning between two stable configurations through shear deformation. The outer shape of the unit cell of this structure is a parallelogram, with its upper and lower sides forming the bases of two solid triangles. The vertices from these triangles within the parallelogram are linked by short beams, while the remaining vertices are linked by long beams. The elastic energy of the essential model of the metamaterial was formulated analytically. The energy barrier between these two stable configurations consists of the elastic strain energy due to the tensile deformation of the short beams, the compressive deformation of the long beams, and the bending deformation of the connecting hinges. One example of a novel metamaterial was additively manufactured via the materials extrusion (MEX) process of thermoplastic polyurethane. The metamaterial exhibited deformation behaviors characteristic of martensitic transformations. This mechanical metamaterial has the potential to obtain properties caused by martensitic transformation in actual materials, such as the shape memory effect and superelasticity.

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Section: Introductionmentioning

confidence: 99%

Martensitic Phase-Transforming Metamaterial: Concept and Model

Kanegae,

Okugawa,

Koizumi

2023

Materials

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Auxetic Two‐Phase Chevron Mechanical Metamaterial

Xu,

Nash,

Batwa

et al. 2024

Adv Eng Mater

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This investigation explores novel two‐phase chevron mechanical metamaterials that exhibit auxetic properties. Unlike traditional foam‐like cellular or porous auxetic materials, these designs are composed of chevron patterned layers embedded in anisotropic matrix. This innovation design allows for auxeticity in two orthogonal in‐plane directions (bi‐auxeticity) or in all in‐plane directions (complete auxeticity), providing not only a general strategy but also detailed guidelines for designing non‐porous auxetic mechanical metamaterials with tunable auxetic behaviors. One goal of this work is to explore the mechanical behavior, specifically effective stiffness and Poisson's ratio, of these new designs and to identify the design space for auxetic behavior using numerical and experimental methods. Systematic finite element (FE) simulations are conducted using ABAQUS and Python scripts to quantify effective stiffness and Poisson's ratio within a small strain range. To validate the numerical predictions, three representative designs are selected and fabricated via multi‐material polymer jetting. Uniaxial tension experiments are conducted on these specimens. Design spaces for non‐auxeticity, partial‐auxeticity, and complete auxeticity are identified through an integrated numerical approach. Theoretical criteria for determining the completeness of auxeticity are proposed and verified via FE simulations.

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Energy absorption characteristic of auxetic metamaterials honeycombs and lattices with negative thermal expansion

Zhang,

Sun

2025

Thin-Walled Structures

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Thermal Expansion of Hybrid Chiral Mechanical Metamaterial with Patterned Bi‐Strips

Cited by 3 publications

References 51 publications

Martensitic Phase-Transforming Metamaterial: Concept and Model

Martensitic Phase-Transforming Metamaterial: Concept and Model

Auxetic Two‐Phase Chevron Mechanical Metamaterial

Energy absorption characteristic of auxetic metamaterials honeycombs and lattices with negative thermal expansion

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