Unconventional locomotion of liquid metal droplets driven by magnetic fields
Unconventional locomotion of liquid metal droplets driven by magnetic fields
The locomotion of liquid metal droplets enables enormous potential for realizing various applications in microelectromechanical systems (MEMSs), biomimetics, and microfluidics. However, current techniques for actuating liquid metal droplets are either associated with intense electrochemical reactions or require modification of their physical properties by coating/mixing them with other materials. These methods either generate gas bubbles or compromise the stability and liquidity of the liquid metal. Here, we introduce an innovative method for controlling the locomotion of liquid metal droplets using Lorentz force induced by magnetic fields. Remarkably, utilizing a magnetic field to induce actuation avoids the generation of gas bubbles in comparison to the method of forming a surface tension gradient on the liquid metal using electrochemistry. In addition, the use of Lorentz force avoids the need of mixing liquid metals with ferromagnetic materials, which may compromise the liquidity of liquid metals. Most importantly, we discover that the existence of a slip layer for liquid metal droplets distinguishes their actuation behaviors from solid metallic spheres. We investigate the parameters affecting the actuation behavior of liquid metal droplets and explore the science behind its operation. We further conducted a series of proof-of-concept experiments to verify the controllability of our method for actuating liquid metal droplets. As such, we believe that the presented technique represents a significant advance in comparison to reported actuation methods for liquid metals, and possesses the potential to be readily adapted by other systems to advance the fields of MEMS actuation and soft robotics.
7113-7118
Shu, Jian
10c82f94-8f99-4785-b33f-fa20484344fd
Tang, Shi Yang
1d0f15c6-2a3e-4bad-a3d8-fc267db93ed4
Feng, Zhihua
4d3c9f9a-6fee-4fbe-863d-bd504d95be04
Li, Weihua
e2555036-0e48-425a-afeb-db6ffba5238e
Li, Xiangpeng
73f32905-ad7c-4ce3-93a4-78237b98f4fb
Zhang, Shiwu
da008f91-71fa-42fb-879e-68b91429e1d6
2018
Shu, Jian
10c82f94-8f99-4785-b33f-fa20484344fd
Tang, Shi Yang
1d0f15c6-2a3e-4bad-a3d8-fc267db93ed4
Feng, Zhihua
4d3c9f9a-6fee-4fbe-863d-bd504d95be04
Li, Weihua
e2555036-0e48-425a-afeb-db6ffba5238e
Li, Xiangpeng
73f32905-ad7c-4ce3-93a4-78237b98f4fb
Zhang, Shiwu
da008f91-71fa-42fb-879e-68b91429e1d6
Shu, Jian, Tang, Shi Yang, Feng, Zhihua, Li, Weihua, Li, Xiangpeng and Zhang, Shiwu
(2018)
Unconventional locomotion of liquid metal droplets driven by magnetic fields.
Soft Matter, 14 (35), .
(doi:10.1039/c8sm01281d).
Abstract
The locomotion of liquid metal droplets enables enormous potential for realizing various applications in microelectromechanical systems (MEMSs), biomimetics, and microfluidics. However, current techniques for actuating liquid metal droplets are either associated with intense electrochemical reactions or require modification of their physical properties by coating/mixing them with other materials. These methods either generate gas bubbles or compromise the stability and liquidity of the liquid metal. Here, we introduce an innovative method for controlling the locomotion of liquid metal droplets using Lorentz force induced by magnetic fields. Remarkably, utilizing a magnetic field to induce actuation avoids the generation of gas bubbles in comparison to the method of forming a surface tension gradient on the liquid metal using electrochemistry. In addition, the use of Lorentz force avoids the need of mixing liquid metals with ferromagnetic materials, which may compromise the liquidity of liquid metals. Most importantly, we discover that the existence of a slip layer for liquid metal droplets distinguishes their actuation behaviors from solid metallic spheres. We investigate the parameters affecting the actuation behavior of liquid metal droplets and explore the science behind its operation. We further conducted a series of proof-of-concept experiments to verify the controllability of our method for actuating liquid metal droplets. As such, we believe that the presented technique represents a significant advance in comparison to reported actuation methods for liquid metals, and possesses the potential to be readily adapted by other systems to advance the fields of MEMS actuation and soft robotics.
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Published date: 2018
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Funding Information:
This research has been partially supported by the National Natural Science Foundation of China (No. 51375468, 51828503, 61503270). Dr Shi-Yang Tang is the recipient of the Vice-Chancellor’s Postdoctoral Research Fellowship funded by the University of Wollongong.
Publisher Copyright:
© 2018 The Royal Society of Chemistry.
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Local EPrints ID: 481704
URI: http://eprints.soton.ac.uk/id/eprint/481704
ISSN: 1744-683X
PURE UUID: 061d7146-bf68-4c3c-894d-ce5017e59be1
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Date deposited: 06 Sep 2023 16:50
Last modified: 06 Jun 2024 02:18
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Author:
Jian Shu
Author:
Shi Yang Tang
Author:
Zhihua Feng
Author:
Weihua Li
Author:
Xiangpeng Li
Author:
Shiwu Zhang
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