Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity
Autonomous object manipulation and perception with environmental factor-triggered and self-powered actuation is one of the most attractive directions for developing next-generation soft robotics with a smart human-machine-environment interface. Humidity, as a sustainable energy source ubiquitous in...
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sg-ntu-dr.10356-1713692023-10-26T06:57:31Z Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity Zhou, Jiahui Zhang, Yufan Zhang, Jiwei Zhang, Desuo Zhou, Xinran Xiong, Jiaqing School of Materials Science and Engineering Engineering::Materials Autonomous Manipulation Object Manipulation Autonomous object manipulation and perception with environmental factor-triggered and self-powered actuation is one of the most attractive directions for developing next-generation soft robotics with a smart human-machine-environment interface. Humidity, as a sustainable energy source ubiquitous in the surrounding environment, can be used for triggering smart grippers. In this work, it is proposed that by contacts between the gripper and objects upon humidity-induced actuation, real-time distinguishable triboelectric signals can be generated to realize the humidity-driven object manipulation and identification. Herein, a thermo-modified electrospun polyvinylpyrrolidone/poly(acrylic acid)/MIL-88A (T-PPM) nanofibrous film with micro-to-nano cross-scale porosity is developed, and a bilayer humidity-responsive actuator (T-HRA) was designed, mimicking the tamariskoid spikemoss to enhance the humidity-driven actuation. The breathing effect of MIL-88A and hierarchical porous structure of the T-PPM facilitate moisture diffusion and offer huge actuation (2.41 cm-1) with a fast response (0.084 cm-1 s-1). For autonomous object manipulation perception, T-PPM was verified as a tribo-positive material located between paper and silk. Accordingly, the T-HRA was demonstrated as a smart soft gripper that generates a different electric signal upon contact with objects of different material. This work proposes a concept of soft robots that are interactive with the environment for both autonomous object manipulation and information acquisition. This work was supported by Key Laboratory of Textile Science & Technology (Donghua University), Ministry of Education (2232022G-01), the Fundamental Research Funds for the Central Universities (2232023Y-01). National Natural Science Foundation of China (52103254, 52273244). 2023-10-26T06:57:31Z 2023-10-26T06:57:31Z 2023 Journal Article Zhou, J., Zhang, Y., Zhang, J., Zhang, D., Zhou, X. & Xiong, J. (2023). Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity. ACS Nano, 17(18), 17920-17930. https://dx.doi.org/10.1021/acsnano.3c04022 1936-0851 https://hdl.handle.net/10356/171369 10.1021/acsnano.3c04022 37668183 2-s2.0-85171804015 18 17 17920 17930 en ACS Nano © 2023 American Chemical Society. All rights reserved. |
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Engineering::Materials Autonomous Manipulation Object Manipulation Zhou, Jiahui Zhang, Yufan Zhang, Jiwei Zhang, Desuo Zhou, Xinran Xiong, Jiaqing Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| description |
Autonomous object manipulation and perception with environmental factor-triggered and self-powered actuation is one of the most attractive directions for developing next-generation soft robotics with a smart human-machine-environment interface. Humidity, as a sustainable energy source ubiquitous in the surrounding environment, can be used for triggering smart grippers. In this work, it is proposed that by contacts between the gripper and objects upon humidity-induced actuation, real-time distinguishable triboelectric signals can be generated to realize the humidity-driven object manipulation and identification. Herein, a thermo-modified electrospun polyvinylpyrrolidone/poly(acrylic acid)/MIL-88A (T-PPM) nanofibrous film with micro-to-nano cross-scale porosity is developed, and a bilayer humidity-responsive actuator (T-HRA) was designed, mimicking the tamariskoid spikemoss to enhance the humidity-driven actuation. The breathing effect of MIL-88A and hierarchical porous structure of the T-PPM facilitate moisture diffusion and offer huge actuation (2.41 cm-1) with a fast response (0.084 cm-1 s-1). For autonomous object manipulation perception, T-PPM was verified as a tribo-positive material located between paper and silk. Accordingly, the T-HRA was demonstrated as a smart soft gripper that generates a different electric signal upon contact with objects of different material. This work proposes a concept of soft robots that are interactive with the environment for both autonomous object manipulation and information acquisition. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Zhou, Jiahui Zhang, Yufan Zhang, Jiwei Zhang, Desuo Zhou, Xinran Xiong, Jiaqing |
| format |
Article |
| author |
Zhou, Jiahui Zhang, Yufan Zhang, Jiwei Zhang, Desuo Zhou, Xinran Xiong, Jiaqing |
| author_sort |
Zhou, Jiahui |
| title |
Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| title_short |
Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| title_full |
Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| title_fullStr |
Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| title_full_unstemmed |
Breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| title_sort |
breathable metal–organic framework enhanced humidity-responsive nanofiber actuator with autonomous triboelectric perceptivity |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171369 |
| _version_ |
1781793684915748864 |