Stroking through electrolyte: liquid metal droplet propulsion through pulse time modulation
Stroking through electrolyte: liquid metal droplet propulsion through pulse time modulation
Active droplets play important roles in microfluidics, robotics, and micro-electromechanical systems. As a special class of active droplets that are conductive, reactive, and of high surface tension, liquid metal droplets (LMDs) can be driven by electric-field-induced surface (Marangoni) flows to function as reconfigurable components in actuators, sensors, catalytic reactors, and antennas. Stimulating LMDs using an electric field induces concurrent electro-hydrodynamic flows and electrochemical surface oxidation (passivation). It is however difficult to decouple these two effects which brings complexity in controlling LMD motions. To address this challenge, pulse time modulation (PTM) signals are used. PTM enables controlled LMD displacement by propelling the droplets forward during the voltage-on phases and facilitating surface recovery from oxidation during the voltage-off phases. Counterintuitively, by taking such intermittent “rests”, the LMDs effectively inhibit the unfavorable impact of oxidation, granting high motion controllability. Combining high-speed imaging, motion tracking, machine learning, and electrochemical analysis, the study reveals how electro-hydrodynamic flows and surface oxide formation/dissolution interplay to generate well-defined motion regimes. The study further develops a quasi-analytical model to describe droplet motions and designs a rotary LMD motor to showcase the versatility of the approach. This work provides the fundamental framework and viable strategy for designing innovative liquid metal-based systems.
active droplets, liquid metal, Marangoni flow, pulse time modulation, surface tension
Fuchs, Richard
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Abdoli, Shiva
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Kilani, Mohamed
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Nor-Azman, Nur Adania
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Yu, Ruohan
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Tang, Shi Yang
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Dickey, Michael D.
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Mao, Guangzhao
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Kalantar-Zadeh, Kourosh
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Tang, Jianbo
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25 April 2024
Fuchs, Richard
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Abdoli, Shiva
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Kilani, Mohamed
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Nor-Azman, Nur Adania
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Yu, Ruohan
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Tang, Shi Yang
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Dickey, Michael D.
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Mao, Guangzhao
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Kalantar-Zadeh, Kourosh
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Tang, Jianbo
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Fuchs, Richard, Abdoli, Shiva, Kilani, Mohamed, Nor-Azman, Nur Adania, Yu, Ruohan, Tang, Shi Yang, Dickey, Michael D., Mao, Guangzhao, Kalantar-Zadeh, Kourosh and Tang, Jianbo
(2024)
Stroking through electrolyte: liquid metal droplet propulsion through pulse time modulation.
Advanced Functional Materials, 34 (17), [2314815].
(doi:10.1002/adfm.202314815).
Abstract
Active droplets play important roles in microfluidics, robotics, and micro-electromechanical systems. As a special class of active droplets that are conductive, reactive, and of high surface tension, liquid metal droplets (LMDs) can be driven by electric-field-induced surface (Marangoni) flows to function as reconfigurable components in actuators, sensors, catalytic reactors, and antennas. Stimulating LMDs using an electric field induces concurrent electro-hydrodynamic flows and electrochemical surface oxidation (passivation). It is however difficult to decouple these two effects which brings complexity in controlling LMD motions. To address this challenge, pulse time modulation (PTM) signals are used. PTM enables controlled LMD displacement by propelling the droplets forward during the voltage-on phases and facilitating surface recovery from oxidation during the voltage-off phases. Counterintuitively, by taking such intermittent “rests”, the LMDs effectively inhibit the unfavorable impact of oxidation, granting high motion controllability. Combining high-speed imaging, motion tracking, machine learning, and electrochemical analysis, the study reveals how electro-hydrodynamic flows and surface oxide formation/dissolution interplay to generate well-defined motion regimes. The study further develops a quasi-analytical model to describe droplet motions and designs a rotary LMD motor to showcase the versatility of the approach. This work provides the fundamental framework and viable strategy for designing innovative liquid metal-based systems.
Text
Adv Funct Materials - 2024 - Fuchs - Stroking through Electrolyte Liquid Metal Droplet Propulsion through Pulse Time
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e-pub ahead of print date: 4 January 2024
Published date: 25 April 2024
Keywords:
active droplets, liquid metal, Marangoni flow, pulse time modulation, surface tension
Identifiers
Local EPrints ID: 503374
URI: http://eprints.soton.ac.uk/id/eprint/503374
ISSN: 1616-301X
PURE UUID: 63900b22-7c53-401a-9a33-1c7ce5dd9633
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Date deposited: 30 Jul 2025 16:30
Last modified: 22 Aug 2025 02:40
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Contributors
Author:
Richard Fuchs
Author:
Shiva Abdoli
Author:
Mohamed Kilani
Author:
Nur Adania Nor-Azman
Author:
Ruohan Yu
Author:
Shi Yang Tang
Author:
Michael D. Dickey
Author:
Guangzhao Mao
Author:
Kourosh Kalantar-Zadeh
Author:
Jianbo Tang
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