Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines
Microengines driven by catalytic decomposition of a fuel have been an interesting research area recently due to their diverse applications, such as environmental monitoring and drug delivery. Literature reports a number of studies on this topic where researchers have made various attempts to manufac...
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sg-ntu-dr.10356-1748812024-04-20T16:49:45Z Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines Perera, Adhikarige Taniya Kaushalya Song, Kewei Meng, Xiangyi Wan, Wei Yang Umezu, Shinjiro Sato, Hirotaka School of Mechanical and Aerospace Engineering Engineering Self-propelled catalytic engines Additive manufacturing Microengines driven by catalytic decomposition of a fuel have been an interesting research area recently due to their diverse applications, such as environmental monitoring and drug delivery. Literature reports a number of studies on this topic where researchers have made various attempts to manufacture such microengines. Some such methods are deposition of catalytic metal layers on sacrificial photoresists, electrochemical deposition of metal layers on polymeric structures, or 3D printing of structures followed by multi-step loading of structures with catalysts. These methods, even though proven to be effective, are tedious, time-consuming, and expensive. To address these issues, herein we report a 3D printing technique to realize microengines in a simple, rapid, and inexpensive single-step process. The printing of various shapes of microengines is achieved using digital light processing printing of a catalyst resin, where Pd(II) acts as a catalyst resin. The proposed integrated molding process can achieve cost-effective preparation of high-efficiency microengines. We demonstrate the locomotion of these microengines in 30% (w/w) H2O2 through the decomposition of H2O2 to generate oxygen to facilitate the self-propelled locomotion. The study characterizes the microengine based on several factors, such as the role of H2O2, Pd, shape, and design of the microengine, to get a full picture of the self-locomotion of microengines. The study shows that the developed method is feasible to manufacture microengines in a simple, rapid, and inexpensive manner to be suitable for numerous applications such as environmental monitoring, remediation, drug delivery, diagnosis, etc., through the modification of the catalyst resin and fuel, as desired. Ministry of Education (MOE) Nanyang Technological University Published version This work was supported by the Singapore Ministry of Education [RG140/20], NTUitive Pte Ltd [NGF-2022-11- 020], JST SPRING (grant number JPMJSP2128), JST-Mirai Program (grant number JPMJMI21I1), and KAKENHI (grant numbers 19H02117 and 20K20986), Japan, and Frontier of Embodiment Informatics: ICT and Robotics, under Waseda University’s Waseda Goes Global Plan, as part of The Japanese Ministry of Education, Culture, Sports, Science and Technology (MEXT)’s Top Global University Project. 2024-04-15T05:38:32Z 2024-04-15T05:38:32Z 2024 Journal Article Perera, A. T. K., Song, K., Meng, X., Wan, W. Y., Umezu, S. & Sato, H. (2024). Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines. ACS Omega, 9(1), 283-293. https://dx.doi.org/10.1021/acsomega.3c04949 2470-1343 https://hdl.handle.net/10356/174881 10.1021/acsomega.3c04949 38222604 2-s2.0-85181833969 1 9 283 293 en RG140/20 NGF-2022-11- 020 ACS Omega © 2023 The Authors. Published by American Chemical Society. This publication is licensed under CC-BY-NC-ND 4.0. application/pdf |
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Engineering Self-propelled catalytic engines Additive manufacturing Perera, Adhikarige Taniya Kaushalya Song, Kewei Meng, Xiangyi Wan, Wei Yang Umezu, Shinjiro Sato, Hirotaka Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
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Microengines driven by catalytic decomposition of a fuel have been an interesting research area recently due to their diverse applications, such as environmental monitoring and drug delivery. Literature reports a number of studies on this topic where researchers have made various attempts to manufacture such microengines. Some such methods are deposition of catalytic metal layers on sacrificial photoresists, electrochemical deposition of metal layers on polymeric structures, or 3D printing of structures followed by multi-step loading of structures with catalysts. These methods, even though proven to be effective, are tedious, time-consuming, and expensive. To address these issues, herein we report a 3D printing technique to realize microengines in a simple, rapid, and inexpensive single-step process. The printing of various shapes of microengines is achieved using digital light processing printing of a catalyst resin, where Pd(II) acts as a catalyst resin. The proposed integrated molding process can achieve cost-effective preparation of high-efficiency microengines. We demonstrate the locomotion of these microengines in 30% (w/w) H2O2 through the decomposition of H2O2 to generate oxygen to facilitate the self-propelled locomotion. The study characterizes the microengine based on several factors, such as the role of H2O2, Pd, shape, and design of the microengine, to get a full picture of the self-locomotion of microengines. The study shows that the developed method is feasible to manufacture microengines in a simple, rapid, and inexpensive manner to be suitable for numerous applications such as environmental monitoring, remediation, drug delivery, diagnosis, etc., through the modification of the catalyst resin and fuel, as desired. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Perera, Adhikarige Taniya Kaushalya Song, Kewei Meng, Xiangyi Wan, Wei Yang Umezu, Shinjiro Sato, Hirotaka |
format |
Article |
author |
Perera, Adhikarige Taniya Kaushalya Song, Kewei Meng, Xiangyi Wan, Wei Yang Umezu, Shinjiro Sato, Hirotaka |
author_sort |
Perera, Adhikarige Taniya Kaushalya |
title |
Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
title_short |
Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
title_full |
Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
title_fullStr |
Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
title_full_unstemmed |
Metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
title_sort |
metal-plastic hybrid additive manufacturing to realize small-scale self-propelled catalytic engines |
publishDate |
2024 |
url |
https://hdl.handle.net/10356/174881 |
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1800916241166106624 |