Hierarchical tessellation enables programmable morphing matter
Shape-morphing materials offer feasible pathways for mimicking adaptive biological organisms that can transform between various morphologies. However, existing morphing strategies through pre-arranged localized strain and/or cut/fold patterns have a limited range of achievable geometries, and the mo...
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sg-ntu-dr.10356-1779062024-06-03T02:16:00Z Hierarchical tessellation enables programmable morphing matter Yang, Xudong Liu, Mingchao Zhang, Bojian Wang, Ziqi Chen, Tianyu Zhou, Yuan Chen, Yu Hsia, K. Jimmy Wang, Yifan School of Mechanical and Aerospace Engineering School of Chemistry, Chemical Engineering and Biotechnology Engineering Hierarchical tessellation Morphing matter Shape-morphing materials offer feasible pathways for mimicking adaptive biological organisms that can transform between various morphologies. However, existing morphing strategies through pre-arranged localized strain and/or cut/fold patterns have a limited range of achievable geometries, and the morphed structures usually have low stiffness due to the intrinsic softness of underlying materials. To address these challenges, we propose an inverse-design framework via tessellating target 3D geometries at two different levels: kirigami tessellation at the global level and particle tessellation at the local level, referred as “hierarchical tessellation.” Upon actuation, general 3D geometries such as varying curvature and asymmetry, and tunable stiffness can be reversibly achieved by assembling rigid tessellated building blocks from a 2D surface. We demonstrate its applications with an interactive lamp, a protective rescue channel, and the smart actuation with electrothermal actuators. Our framework provides guidelines for designing programmable matter with high morphing capabilities and respectable mechanical robustness for multiscale applications. Agency for Science, Technology and Research (A*STAR) Nanyang Technological University This work was funded by the AME YIRG award (A2084c0162) and MTC IRG award (M21K2c0118) from the Singapore Agency for Science, Technology and Research (A*STAR). We also acknowledge the following support from the Nanyang Technological University, Singapore: Y.W. acknowledges the NAP award (020482); M.L. acknowledges the Presidential Postdoctoral Fellowship; and K.J.H. acknowledges the Start Up Grant (002271-00001). 2024-06-03T02:16:00Z 2024-06-03T02:16:00Z 2024 Journal Article Yang, X., Liu, M., Zhang, B., Wang, Z., Chen, T., Zhou, Y., Chen, Y., Hsia, K. J. & Wang, Y. (2024). Hierarchical tessellation enables programmable morphing matter. Matter, 7(2), 603-619. https://dx.doi.org/10.1016/j.matt.2023.11.002 2590-2385 https://hdl.handle.net/10356/177906 10.1016/j.matt.2023.11.002 2-s2.0-85180740680 2 7 603 619 en A2084c0162 M21K2c0118 NAP (020482) 002271- 00001 Matter © 2023 Elsevier Inc. All rights reserved. |
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Engineering Hierarchical tessellation Morphing matter |
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Engineering Hierarchical tessellation Morphing matter Yang, Xudong Liu, Mingchao Zhang, Bojian Wang, Ziqi Chen, Tianyu Zhou, Yuan Chen, Yu Hsia, K. Jimmy Wang, Yifan Hierarchical tessellation enables programmable morphing matter |
| description |
Shape-morphing materials offer feasible pathways for mimicking adaptive biological organisms that can transform between various morphologies. However, existing morphing strategies through pre-arranged localized strain and/or cut/fold patterns have a limited range of achievable geometries, and the morphed structures usually have low stiffness due to the intrinsic softness of underlying materials. To address these challenges, we propose an inverse-design framework via tessellating target 3D geometries at two different levels: kirigami tessellation at the global level and particle tessellation at the local level, referred as “hierarchical tessellation.” Upon actuation, general 3D geometries such as varying curvature and asymmetry, and tunable stiffness can be reversibly achieved by assembling rigid tessellated building blocks from a 2D surface. We demonstrate its applications with an interactive lamp, a protective rescue channel, and the smart actuation with electrothermal actuators. Our framework provides guidelines for designing programmable matter with high morphing capabilities and respectable mechanical robustness for multiscale applications. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Yang, Xudong Liu, Mingchao Zhang, Bojian Wang, Ziqi Chen, Tianyu Zhou, Yuan Chen, Yu Hsia, K. Jimmy Wang, Yifan |
| format |
Article |
| author |
Yang, Xudong Liu, Mingchao Zhang, Bojian Wang, Ziqi Chen, Tianyu Zhou, Yuan Chen, Yu Hsia, K. Jimmy Wang, Yifan |
| author_sort |
Yang, Xudong |
| title |
Hierarchical tessellation enables programmable morphing matter |
| title_short |
Hierarchical tessellation enables programmable morphing matter |
| title_full |
Hierarchical tessellation enables programmable morphing matter |
| title_fullStr |
Hierarchical tessellation enables programmable morphing matter |
| title_full_unstemmed |
Hierarchical tessellation enables programmable morphing matter |
| title_sort |
hierarchical tessellation enables programmable morphing matter |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/177906 |
| _version_ |
1814047160675598336 |