Are Contact Angle Measurements Useful for Oxide-Coated Liquid Metals?

Joshipura, Ishan D.; Persson, Karl A.; Truong, Vi Khanh; Oh, Ji‐Hyun; Kong, Minsik; Vong, Man Hou; Ni, Chujun; Alsafatwi, Mohanad; Parekh, Dishit P.; Zhao, Hong; Dickey, Michael D.

doi:10.1021/acs.langmuir.1c01173

Cited by 64 publications

(73 citation statements)

References 77 publications

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“…To address these issues, we have previously presented the use of a liquid metal as a liquid with a barely measurable evaporation rate [22] and demonstrated robotically assisted contact angle measurements in a scanning electron microscope (SEM) [23]. To address the issue of oxide layer growth on the liquid metal droplets, which would prevent them from being useful for contact angle measurements [24], our experiments take place in the low-oxygen vacuum atmosphere of an SEM chamber.…”

Section: Introductionmentioning

confidence: 99%

Line Tension and Drop Size Dependence of Contact Angle at the Nanoscale

2022

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Despite considerable research efforts, the influence of contact line tension during wetting at the nanoscale and its experimental determination remain challenging tasks. So far, molecular dynamics simulations and atomic force microscope measurements have contributed to the understanding of these phenomena. However, a direct measurement of the size dependence of the contact angle and the magnitude of the apparent line tension has not been realized so far. Here, we show that the contact angle is indeed dependent on the drop size for small drop diameters and determine the magnitude of the apparent line tension via liquid-metal based measurements of advancing and receding contact angle inside a scanning electron microscope. For this purpose, a robotic setup inside an electron microscope chamber and oxide-free Galinstan droplets—produced via an electromigration-based and focused ion beam irradiation-assisted process—are employed. Using the first-order correction of Young’s equation, we find an apparent line tension value of 4.02 × 10−7 J/m for Galinstan© on stainless steel.

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Section: Introductionmentioning

confidence: 99%

Line Tension and Drop Size Dependence of Contact Angle at the Nanoscale

2022

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“…NaOH (1M) was used as an electrolyte to create a basic pH environment that dissolves the surface oxide of the liquid metal, 37 which would otherwise interfere with the wetting dynamics and contact angle. 38 The dissolution of gallium oxide proceeds through the following reaction 39 Ga O 2NaOH 3H O 2Na Ga(OH) Resonant Frequency. The resonant frequency (ω) of a freely oscillating liquid droplet for the nth mode oscillation is given as 41−43 ω 2 = (σ LV n(n − 1)(n + 2)/ρ)q 3 , where σ LV is the interfacial tension of the liquid metal and surrounding electrolyte interface, n is the mode number, ρ is the density of EGaIn, and q is the characteristic length of the droplet.…”

Section: ■ Materials and Methodsmentioning

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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“…Prior to electrode printing, the contact angles made by water and EGaIn on the composite (PGNC@6wt %) were compared to that of pure PDMS and no significant difference was observed (Figure 7a-d) which indicated negligible changes in surface wetting behaviors by the GNF fillers. Receding the EGaIn droplets left behind traces of oxide (Figure 7e-h) which signifies oxide-substrate adhesion possibly by van der Waals interaction [89]. Using the camera of the contact angle goniometer, tilting of a tiny droplet of pure EGaIn on composite was recorded (Video S1) and it was observed that the droplet adhered to the composite even when the tilt angle was 90 • , signifying resistive adhesive force of the droplet's oxide layer to the composite's surface against gravitational force [38].…”

Section: Oxidized Egain As Soft and Stretchable Electrodementioning

confidence: 96%

Liquid Metal Patterned Stretchable and Soft Capacitive Sensor with Enhanced Dielectric Property Enabled by Graphite Nanofiber Fillers

et al. 2022

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In this work, we introduce liquid metal patterned stretchable and soft capacitive sensor with enhanced dielectric properties enabled by graphite nanofiber (GNF) fillers dispersed in polydimethylsiloxane (PDMS) substrate. We oxidized gallium-based liquid metal that exhibited excellent wetting behavior on the surface of the composites to enable patterning of the electrodes by a facile stencil printing. The fluidic behavior of the liquid metal electrode and modulated dielectric properties of the composite (k = 6.41 ± 0.092@6 wt % at 1 kHz) was utilized to fabricate stretchable and soft capacitive sensor with ability to distinguish various hand motions.

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Are Contact Angle Measurements Useful for Oxide-Coated Liquid Metals?

Cited by 64 publications

References 77 publications

Line Tension and Drop Size Dependence of Contact Angle at the Nanoscale

Line Tension and Drop Size Dependence of Contact Angle at the Nanoscale

Electrically Induced Liquid Metal Droplet Bouncing

Liquid Metal Patterned Stretchable and Soft Capacitive Sensor with Enhanced Dielectric Property Enabled by Graphite Nanofiber Fillers

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