Jinpyo Jeon scite author profile

We report magnetic-field-driven on-demand manipulation of liquid metal in microfluidic channels filled with base or acid. The liquid metal was coated with iron (Fe) particles and treated with hydrochloric acid to have strong bonding strength with the Fe particles. The magnetic liquid metal slug inserted in the microchannel is manipulated, merged, and separated. In addition, corresponding to the repositioning of an external magnet, the liquid metal slug can be readily moved in microfluidic channels with different angles (>90°) and cross-linked channels in any direction. We demonstrated the functionality of the liquid metal in the microfluidic channel for electrical switching applications by manipulation of the liquid metal, resulting in the sequential turning on of light emitting diodes (LEDs).

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Magnetic Liquid Metal Marble: Characterization of Lyophobicity and Magnetic Manipulation for Switching Applications

Jeon

Lee

Chung

et al. 2016

J. Microelectromech. Syst.

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Acoustic bubble-powered miniature rotor for wireless energy harvesting in a liquid medium

Jang

Jeon

Chung

2018

Sensors and Actuators A: Physical

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Acoustic wave-driven oxidized liquid metal-based energy harvester

Jeon

Chung

Lee³

et al. 2018

Eur. Phys. J. Appl. Phys.

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We report an oxidized liquid metal droplet-based energy harvester that converts acoustic energy into electrical energy by modulating an electrical double layer that originates from the deformation of the oxidized liquid metal droplet. Gallium-based liquid metal alloy has been developed for various applications owing to the outstanding material properties, such as its high electrical conductivity (metallic property) and unlimited deformability (liquid property). In this study, we demonstrated energy harvesting using an electrical double layer between the acoustic wave-modulated liquid metal droplet and two electrodes. The proposed energy harvester consisted of top and bottom electrodes covered with the dielectric layer and a Gallium-based liquid metal droplet placed between the electrodes. When we applied an external bias voltage and acoustic wave to the proposed device, the contact area between the liquid metal droplet and the electrodes changed, leading to the variation of the capacitance in the electrical double layer and the generation of electrical output current. Using the proposed energy harvester, the maximum output current of 41.2 nA was generated with an applied acoustic wave of 30 Hz. In addition, we studied the relationships between the maximum output current and a variety of factors, such as the size of the liquid metal droplet, the thickness of the hydrophobic layer, and the distance between the top and bottom electrode plates.

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On-demand frequency tunability of fluidic antenna implemented with gallium-based liquid metal alloy

Kim

Doo

Won

et al. 2017

Eur. Phys. J. Appl. Phys.

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Jinpyo Jeon

On-demand magnetic manipulation of liquid metal in microfluidic channels for electrical switching applications

Magnetic Liquid Metal Marble: Characterization of Lyophobicity and Magnetic Manipulation for Switching Applications

Acoustic bubble-powered miniature rotor for wireless energy harvesting in a liquid medium

Acoustic wave-driven oxidized liquid metal-based energy harvester

On-demand frequency tunability of fluidic antenna implemented with gallium-based liquid metal alloy

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