Unconstrained 3D shape programming with light-induced stress gradient
Programming 2D sheets to form 3D shapes is significant for flexible electronics, soft robots, and biomedical devices. Stress regulation is one of the most used methods, during which external force is usually needed to keep the stress, leading to complex processing setups. Here, by introducing dynami...
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sg-ntu-dr.10356-1607062022-08-01T05:46:24Z Unconstrained 3D shape programming with light-induced stress gradient Liu, Cheng Tan, Yizheng He, Chaowei Ji, Shaobo Xu, Huaping School of Materials Science and Engineering Engineering::Materials 3D Shape Programming Dynamic Covalent Bond Programming 2D sheets to form 3D shapes is significant for flexible electronics, soft robots, and biomedical devices. Stress regulation is one of the most used methods, during which external force is usually needed to keep the stress, leading to complex processing setups. Here, by introducing dynamic diselenide bonds into shape-memory materials, unconstrained shape programming with light is achieved. The material could hold and release internal stress by themselves through the shape-memory effect, simplifying programming setups. The fixed stress could be relaxed by light to form stress gradients, leading to out-of-plane deformations through asymmetric contractions. Benefiting from the variability of light irradiation, complex 3D configurations can be obtained conveniently from 2D polymer sheets. Besides, remotely controlled "4D assembly" and actuation, including object transportation and self-lifting, can be achieved by sequential deformation. Taking advantage of the high spatial resolution of light, this material can also produce 3D microscopic patterns. The light-induced stress gradients significantly simplify 3D shape programming procedures with improved resolution and complexity and have great potential in soft robots, smart actuators, and anti-counterfeiting techniques. This work was financially supported by National Natural Science Foundation of China (21734006) and the Foundation for Innovative Research Group of National Natural Science Foundation of China (21821001). 2022-08-01T05:46:23Z 2022-08-01T05:46:23Z 2021 Journal Article Liu, C., Tan, Y., He, C., Ji, S. & Xu, H. (2021). Unconstrained 3D shape programming with light-induced stress gradient. Advanced Materials, 33(42), 2105194-. https://dx.doi.org/10.1002/adma.202105194 0935-9648 https://hdl.handle.net/10356/160706 10.1002/adma.202105194 34476852 2-s2.0-85114108967 42 33 2105194 en Advanced Materials © 2021 Wiley-VCH GmbH. All rights reserved. |
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Engineering::Materials 3D Shape Programming Dynamic Covalent Bond Liu, Cheng Tan, Yizheng He, Chaowei Ji, Shaobo Xu, Huaping Unconstrained 3D shape programming with light-induced stress gradient |
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Programming 2D sheets to form 3D shapes is significant for flexible electronics, soft robots, and biomedical devices. Stress regulation is one of the most used methods, during which external force is usually needed to keep the stress, leading to complex processing setups. Here, by introducing dynamic diselenide bonds into shape-memory materials, unconstrained shape programming with light is achieved. The material could hold and release internal stress by themselves through the shape-memory effect, simplifying programming setups. The fixed stress could be relaxed by light to form stress gradients, leading to out-of-plane deformations through asymmetric contractions. Benefiting from the variability of light irradiation, complex 3D configurations can be obtained conveniently from 2D polymer sheets. Besides, remotely controlled "4D assembly" and actuation, including object transportation and self-lifting, can be achieved by sequential deformation. Taking advantage of the high spatial resolution of light, this material can also produce 3D microscopic patterns. The light-induced stress gradients significantly simplify 3D shape programming procedures with improved resolution and complexity and have great potential in soft robots, smart actuators, and anti-counterfeiting techniques. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Liu, Cheng Tan, Yizheng He, Chaowei Ji, Shaobo Xu, Huaping |
| format |
Article |
| author |
Liu, Cheng Tan, Yizheng He, Chaowei Ji, Shaobo Xu, Huaping |
| author_sort |
Liu, Cheng |
| title |
Unconstrained 3D shape programming with light-induced stress gradient |
| title_short |
Unconstrained 3D shape programming with light-induced stress gradient |
| title_full |
Unconstrained 3D shape programming with light-induced stress gradient |
| title_fullStr |
Unconstrained 3D shape programming with light-induced stress gradient |
| title_full_unstemmed |
Unconstrained 3D shape programming with light-induced stress gradient |
| title_sort |
unconstrained 3d shape programming with light-induced stress gradient |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160706 |
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1743119587107405824 |