Acoustic wave-driven oxidized liquid metal-based energy harvester

Jeon, Jinpyo; Chung, Sang Kug; Lee, Jeong; Doo, Seok Joo; Kim, Dae-Young

doi:10.1051/epjap/2018180011

Cited by 17 publications

(19 citation statements)

References 25 publications

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“…Gallium-based liquid metals, such as eutectic GaIn (75% gallium and 25% indium) and Galinstan (68.5% gallium, 21.5% indium, and 10% tin) have emerged in recent years as nontoxic alternatives for mercury. − These alloys exhibit a unique combination of high thermal and electrical conductivity as a metal yet remain deformable as a liquid at room temperature. ,− This uniqueness in physical properties has enabled gallium-based liquid metal alloys to be utilized in application areas including soft electronics, − sensing, ,− microfluidics, − reconfigurable radio frequency (RF) devices, ,− and energy-harvesting, − among others.…”

Section: Introductionmentioning

confidence: 99%

Surface Modification with Gallium Coating as Nonwetting Surfaces for Gallium-Based Liquid Metal Droplet Manipulation

Chen

Lee

2019

ACS Appl. Mater. Interfaces

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We report gallium (Ga) coating as a simple approach to convert most common microfluidic substrates to nonwetting surfaces against surface-oxidized gallium-based liquid metal alloys. These alloys are readily oxidized in ambient air and adhere to almost all surfaces, which imposes significant challenges in mobilizing liquid metal droplets without leaving residue. Various flat substrates (e.g., PDMS, Si, SiO2, SU-8, glass, and parylene-C coated PDMS) were coated with thin film (75–200 nm in thickness) of gallium by evaporation and the coated gallium formed nanoscale uneven and rough surface through Ostwald ripening with its surface covered with oxide shell. Static and dynamic contact angles of the gallium-coated surfaces were found to be greater than 160°, while dynamic contact angle measurements showed contact angle hysteresis in the range of 6.5–24.4°. Surface-oxidized gallium-based liquid metal alloy droplets were shown to bounce off and roll on the gallium-coated surfaces without leaving any residue which confirms the nonwettability of the gallium-coated flat surfaces. Scanning electron microscopy (SEM) and atomic force microscopy (AFM) showed the gallium-coated flat substrates consist of nanoscale hemispherical structures with average surface roughness of 33.8 nm. Pneumatic actuation of surface-oxidized liquid metal droplets in PDMS microfluidic channels coated with gallium was conducted to confirm the feasibility of utilizing gallium coating as an effective surface modification for surface-oxidized gallium-based liquid metal droplet manipulation.

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Section: Introductionmentioning

confidence: 99%

Surface Modification with Gallium Coating as Nonwetting Surfaces for Gallium-Based Liquid Metal Droplet Manipulation

Chen

Lee

2019

ACS Appl. Mater. Interfaces

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“…Our experimental results show that the decay constant of the underdamped bouncing cycles increases with an increase in voltage and increase in frequency. This study about the electrical control of liquid metal droplet bouncing using a facile AC electrowetting technique can open a plethora of applications such as 3D digital microfluidics, 58 RF switching, 1 energy harvesting, 59 portable lab-on-a-chip applications, 60 and heat transfer systems. 61 …”

Section: Discussionmentioning

confidence: 99%

Electrically Induced Liquid Metal Droplet Bouncing

et al. 2022

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Liquid metals, including eutectic gallium–indium (EGaIn), have been explored for various planar droplet operations, including droplet splitting and merging, promoting their use in emerging areas such as flexible electronics and soft robotics. However, three-dimensional (3D) droplet operations, including droplet bouncing, have mostly been limited to nonmetallic liquids or aqueous solutions. This is the first study of liquid metal droplet bouncing using continuous AC electrowetting through an analytical model, computational fluid dynamics simulation, and empirical validation to the best of our knowledge. We achieved liquid metal droplet bouncing with a height greater than 5 mm with an actuation voltage of less than 10 V and a frequency of less than 5 Hz. We compared the bouncing trajectories of the liquid metal droplet for different actuation parameters. We found that the jumping height of the droplet increases as the frequency of the applied AC voltage decreases and its amplitude increases until the onset of instability. Furthermore, we model the attenuation dynamics of consecutive bouncing cycles of the underdamped droplet bouncing system. This study embarks on controlling liquid metal droplet bouncing electrically, thereby opening a plethora of new opportunities utilizing 3D liquid metal droplet operations for numerous applications such as energy harvesting, heat transfer, and radio frequency (RF) switching.

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“…Reverse electrowetting instead uses mechanical energy to move a droplet of metal into gaps between insulated electrodes. The presence of the metal changes the capacitance between the rigid electrodes and thereby induces charge from a battery to move into the capacitor (78,79). As the metal moves away from the electrodes, the capacitor discharges back to the battery, generating electricity (Figure 4a).…”

Section: Applicationsmentioning

confidence: 99%

Gallium Liquid Metal: The Devil's Elixir

Tang

Tabor

Kalantar‐zadeh

et al. 2021

Annu. Rev. Mater. Res.

179

123

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Gallium is a metal that literally melts in your hand. It has low toxicity, near-zero vapor pressure, and a viscosity similar to water. Despite possessing a surface tension larger than any other liquid (near room temperature), gallium can form nonspherical shapes due to the thin, solid native oxide skin that forms rapidly in oxygen. These properties enable new ways to pattern metals (e.g., injection and printing) to create stretchable and soft devices with an unmatched combination of mechanical and electrical properties. The oxide skin can be transferred to other substrates and manipulated electrochemically to lower the interfacial tension to near zero. The reactivity of gallium can drive a wide range of reactions. Liquids are also easy to break into particles for making colloids and soft composites that have unusual properties due to the deformable nature of the filler. This review summarizes the truly unique and exciting properties of gallium liquid metals. Expected final online publication date for the Annual Review of Materials Science, Volume 51 is August 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Acoustic wave-driven oxidized liquid metal-based energy harvester

Cited by 17 publications

References 25 publications

Surface Modification with Gallium Coating as Nonwetting Surfaces for Gallium-Based Liquid Metal Droplet Manipulation

Surface Modification with Gallium Coating as Nonwetting Surfaces for Gallium-Based Liquid Metal Droplet Manipulation

Electrically Induced Liquid Metal Droplet Bouncing

Gallium Liquid Metal: The Devil's Elixir

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