Temperature-sensitive water-responsive shape memory effect in plant leaves
Some plants have been reported to have the water-induced shape memory effect (SME). Since the tissue system of most plant leaves is a biophysical sandwich-like structure composed of epidermis, mesophyll and veins, the leaves are actually bio-composites. In this paper, we experimentally investigated...
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sg-ntu-dr.10356-1615492022-09-07T07:37:44Z Temperature-sensitive water-responsive shape memory effect in plant leaves Wang, Tao Xi Geng, Yun Hui Wong, Shi Chow Huang, Wei Min Shen, Xing School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Ambient Temperature Soursops Some plants have been reported to have the water-induced shape memory effect (SME). Since the tissue system of most plant leaves is a biophysical sandwich-like structure composed of epidermis, mesophyll and veins, the leaves are actually bio-composites. In this paper, we experimentally investigated the contribution of different tissues to the SME in dried plant leaves (namely, soursop, sugar apple, and longan) and skeleton (i.e., cuticle and lamina removed) leaves (soursop only). Shape recovery in the leave strips, and skeleton soursop leave strips, all programmed (deformed) via rolling and drying, was activated by room temperature water, hot (90 °C) water, or pure heating (up to 230 °C) to uncover the influence of temperature in the SME. Although heating alone does not induce any apparent shape recovery, hot water causes much faster recovery than room temperature water. Besides, same as the influence of the maximum programming strain on the heating-responsive shape recovery in shape memory polymers, less programmed leaves (i.e., with smaller maximum programming strain) tend to recover faster. Together with other tests (including drying, wetting, drying/wetting, cyclic differential scanning calorimetry, etc.), the contributions/roles of different tissues on the phenomena observed in this study are revealed. This work is supported by the National Natural Science Foundation of China (Grant No. 11828201 and No. 11872207) and Natural Science Foundation of Jiangsu Province (Grant No. BK20200413). 2022-09-07T07:37:44Z 2022-09-07T07:37:44Z 2021 Journal Article Wang, T. X., Geng, Y. H., Wong, S. C., Huang, W. M. & Shen, X. (2021). Temperature-sensitive water-responsive shape memory effect in plant leaves. Brazilian Journal of Botany, 44(4), 929-940. https://dx.doi.org/10.1007/s40415-021-00763-3 0100-8404 https://hdl.handle.net/10356/161549 10.1007/s40415-021-00763-3 2-s2.0-85118879848 4 44 929 940 en Brazilian Journal of Botany © 2021 Springer Nature Switzerland AG. Part of Springer Nature. All rights reserved. |
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Engineering::Mechanical engineering Ambient Temperature Soursops Wang, Tao Xi Geng, Yun Hui Wong, Shi Chow Huang, Wei Min Shen, Xing Temperature-sensitive water-responsive shape memory effect in plant leaves |
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Some plants have been reported to have the water-induced shape memory effect (SME). Since the tissue system of most plant leaves is a biophysical sandwich-like structure composed of epidermis, mesophyll and veins, the leaves are actually bio-composites. In this paper, we experimentally investigated the contribution of different tissues to the SME in dried plant leaves (namely, soursop, sugar apple, and longan) and skeleton (i.e., cuticle and lamina removed) leaves (soursop only). Shape recovery in the leave strips, and skeleton soursop leave strips, all programmed (deformed) via rolling and drying, was activated by room temperature water, hot (90 °C) water, or pure heating (up to 230 °C) to uncover the influence of temperature in the SME. Although heating alone does not induce any apparent shape recovery, hot water causes much faster recovery than room temperature water. Besides, same as the influence of the maximum programming strain on the heating-responsive shape recovery in shape memory polymers, less programmed leaves (i.e., with smaller maximum programming strain) tend to recover faster. Together with other tests (including drying, wetting, drying/wetting, cyclic differential scanning calorimetry, etc.), the contributions/roles of different tissues on the phenomena observed in this study are revealed. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Wang, Tao Xi Geng, Yun Hui Wong, Shi Chow Huang, Wei Min Shen, Xing |
| format |
Article |
| author |
Wang, Tao Xi Geng, Yun Hui Wong, Shi Chow Huang, Wei Min Shen, Xing |
| author_sort |
Wang, Tao Xi |
| title |
Temperature-sensitive water-responsive shape memory effect in plant leaves |
| title_short |
Temperature-sensitive water-responsive shape memory effect in plant leaves |
| title_full |
Temperature-sensitive water-responsive shape memory effect in plant leaves |
| title_fullStr |
Temperature-sensitive water-responsive shape memory effect in plant leaves |
| title_full_unstemmed |
Temperature-sensitive water-responsive shape memory effect in plant leaves |
| title_sort |
temperature-sensitive water-responsive shape memory effect in plant leaves |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/161549 |
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