Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields
This paper addresses the trade-off between sensitivity and sensing range in strain sensors, while introducing additional functionalities through an innovative 4D printing approach. The resulting ultraflexible sensor integrates carbon nanotubes/liquid metal hybrids and iron powders within an Ecoflex...
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sg-ntu-dr.10356-1821682025-01-18T16:48:23Z Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields Hou, Yanbei Zhang, Hancen Zhou, Kun School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing Environmental Process Modelling Centre Nanyang Environment and Water Research Institute Engineering 4D printing Magnetic force-driven actuator This paper addresses the trade-off between sensitivity and sensing range in strain sensors, while introducing additional functionalities through an innovative 4D printing approach. The resulting ultraflexible sensor integrates carbon nanotubes/liquid metal hybrids and iron powders within an Ecoflex matrix. The optimization of this composition enables the creation of an uncured resin ideal for Direct Ink Writing (DIW) and a cured sensor with exceptional electromechanical, thermal, and magnetic performance. Notably, the sensor achieves a wide linear strain range of 350% and maintains a stable Gauge Factor of 19.8, offering an ultralow detection limit of 0.1% strain and a rapid 83-ms response time. Beyond superior strain sensing capabilities, the sensor exhibits outstanding thermal endurance for temperatures exceeding 300 °C, enhanced thermal conductivity, and a consistent resistance-temperature relationship, making it well-suited for high-temperature applications. Moreover, the inclusion of iron particles provides magnetic responsiveness, enabling synergistic applications in location and speed detection, particularly in home care. Leveraging DIW facilitates the creation of complex-shaped sensors with multiple functional materials, significantly broadening the sensor's capabilities. This convergence of additive manufacturing and multifunctional materials marks a transformative step in advancing the performance of next-generation sensors across diverse domains. National Research Foundation (NRF) Published version This research was supported by the National Research Foundation, Prime Minister’s Office, Singapore under its Medium-Sized Centre funding scheme through the Marine and Offshore Program. 2025-01-13T04:43:23Z 2025-01-13T04:43:23Z 2024 Journal Article Hou, Y., Zhang, H. & Zhou, K. (2024). Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields. Advanced Science, e2411584-. https://dx.doi.org/10.1002/advs.202411584 2198-3844 https://hdl.handle.net/10356/182168 10.1002/advs.202411584 39718127 2-s2.0-85212875286 e2411584 en Advanced Science © 2024 The Author(s). Advanced Science published by Wiley-VCH GmbH. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. application/pdf |
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Engineering 4D printing Magnetic force-driven actuator |
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Engineering 4D printing Magnetic force-driven actuator Hou, Yanbei Zhang, Hancen Zhou, Kun Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
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This paper addresses the trade-off between sensitivity and sensing range in strain sensors, while introducing additional functionalities through an innovative 4D printing approach. The resulting ultraflexible sensor integrates carbon nanotubes/liquid metal hybrids and iron powders within an Ecoflex matrix. The optimization of this composition enables the creation of an uncured resin ideal for Direct Ink Writing (DIW) and a cured sensor with exceptional electromechanical, thermal, and magnetic performance. Notably, the sensor achieves a wide linear strain range of 350% and maintains a stable Gauge Factor of 19.8, offering an ultralow detection limit of 0.1% strain and a rapid 83-ms response time. Beyond superior strain sensing capabilities, the sensor exhibits outstanding thermal endurance for temperatures exceeding 300 °C, enhanced thermal conductivity, and a consistent resistance-temperature relationship, making it well-suited for high-temperature applications. Moreover, the inclusion of iron particles provides magnetic responsiveness, enabling synergistic applications in location and speed detection, particularly in home care. Leveraging DIW facilitates the creation of complex-shaped sensors with multiple functional materials, significantly broadening the sensor's capabilities. This convergence of additive manufacturing and multifunctional materials marks a transformative step in advancing the performance of next-generation sensors across diverse domains. |
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School of Mechanical and Aerospace Engineering |
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School of Mechanical and Aerospace Engineering Hou, Yanbei Zhang, Hancen Zhou, Kun |
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Article |
| author |
Hou, Yanbei Zhang, Hancen Zhou, Kun |
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Hou, Yanbei |
| title |
Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| title_short |
Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| title_full |
Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| title_fullStr |
Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| title_full_unstemmed |
Ultraflexible sensor development via 4D printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| title_sort |
ultraflexible sensor development via 4d printing: enhanced sensitivity to strain, temperature, and magnetic fields |
| publishDate |
2025 |
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https://hdl.handle.net/10356/182168 |
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1821833180185886720 |