Interfacial Rheology of Gallium-Based Liquid Metals

Jacob, Alan R.; Parekh, Dishit P.; Dickey, Michael D.; Hsiao, Lilian C.

doi:10.1021/acs.langmuir.9b01821

Cited by 85 publications

(78 citation statements)

References 42 publications

(73 reference statements)

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“…Furthermore, we could not mix large particles when they had hierarchical surface features; mesoporous silica and activated alumina with particle sizes up to 200 m were nonmixable; however, regular, nonporous powdered silica is mixable. We It has been observed that when the volume of liquid gallium is small, the behavior of the oxide skin dominates the rheological properties (5,40), showing viscoelastic behavior with a high yield stress (41). We thus propose that GalPs form as shown schematically in figs.…”

Section: Resultsmentioning

confidence: 85%

A general approach to composites containing nonmetallic fillers and liquid gallium

et al. 2021

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We report a versatile method to make liquid metal composites by vigorously mixing gallium (Ga) with non-metallic particles of graphene oxide (G-O), graphite, diamond, and silicon carbide that display either paste or putty-like behavior depending on the volume fraction. Unlike Ga, the putty-like mixtures can be kneaded and rolled on any surface without leaving residue. By changing temperature, these materials can be stiffened, softened, and, for the G-O–containing composite, even made porous. The gallium putty (GalP) containing reduced G-O (rG-O) has excellent electromagnetic interference shielding effectiveness. GalP with diamond filler has excellent thermal conductivity and heat transfer superior to a commercial liquid metal–based thermal paste. Composites can also be formed from eutectic alloys of Ga including Ga-In (EGaIn), Ga-Sn (EGaSn), and Ga-In-Sn (EGaInSn or Galinstan). The versatility of our approach allows a variety of fillers to be incorporated in liquid metals, potentially allowing filler-specific “fit for purpose” materials.

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Section: Resultsmentioning

confidence: 85%

A general approach to composites containing nonmetallic fillers and liquid gallium

et al. 2021

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“…It also avoids the need for shear when printing from a nozzle. As noted previously, liquid metals are low viscosity fluids, having a viscosity on the order of ≈2mPa s. [24,26,81] This should let them be easily aerosolized or jetted, however the extremely large surface tension and presence of a surface oxide complicate using liquid metal in droplet dispensing systems. In brief, it limits the nozzle size.…”

Section: Methodsmentioning

confidence: 99%

“…In fact, this behavior is seen with mercury, which does not rapidly form a native surface oxide, [24] or with EGaIn if the oxide layer is removed. [25] The oxide skin will yield beyond a critical surface stress (≈0.3-0.5 N m −1 ) [5,24,26,27] but otherwise is stable and prevents the metal from flowing in a way that increases area. Similar to surface tension, the pressure required to rupture the surface is simply the critical surface stress multiplied by the curvature of the surface (2/R in the case of a spherical drop, where R is the radius of the drop).…”

Section: Liquid Metalsmentioning

confidence: 99%

“…Bulk liquid metal is a low viscosity (water-like), Newtonian fluid which only obtains a non-Newtonian rheology due to the presence of the solid native oxide on its surface. [24,26,48,49] The low viscosity metal can flow readily within its oxide. However, printing the metal requires dispensing it from a nozzle in a way that increases the surface area, which means the oxide must rupture (and rapidly reform) during printing.…”

Section: Challenges Printing Liquid Metalmentioning

confidence: 99%

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Liquid Metal Direct Write and 3D Printing: A Review

Neumann

Dickey

2020

Adv Materials Technologies

Self Cite

209

170

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This review discusses methods, challenges, and opportunities for direct‐write and 3D printing of low melting point, gallium‐based liquid metal alloys at room temperature. Alloys of gallium exhibit high conductivity and high stretchability making them well suited for use in soft circuitry for stretchable electronics and soft robotics. In addition, the liquid nature of the metal enables entirely new ways to pattern metals at room temperature; herein, the focus is placed on additive printing via nozzle‐based methods. Room temperature printing of liquid metals enables rapid fabrication of complex geometries (with dimensions as small as 10 µm) on a wide range of materials, such as polymers. These processes can be used to make metallic conductors for devices with self‐healing capabilities, soft/stretchable electrodes, and sensors.

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“…[319][320][321] Liquid metals usually have high surface tensions, and an oxide layer occurs on the surface of liquid metal droplets once it is exposed to air. [322,323] DIW and spray coating have been applied to deposit liquid metal electrodes. [324][325][326][327][328][329][330] In addition to the noncontact methods, liquid metal can also be patterned by the contact method.…”

Section: Metal-based Nanomaterialsmentioning

confidence: 99%

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

2020

Advanced Intelligent Systems

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Human-integrated devices include wearable and implantable devices for monitoring vital human signals or interacting with the human body. [1-3] The human-integrated devices needed to be tethered to the organs or the human skin for implementing their functions such as sensing and energy harvesting. [4-18] The economical, agile, customizable manufacturing, and integration of multifunctional device modules into networked systems with mechanical compliance and robustness will enable unprecedented human-integrated smart wearables [19-23] and usher in exciting opportunities in emerging technologies such as electronics, [24-29] wearable computation, [30-36] human-machine interface, [37-42] robotics, [43-48] and advanced healthcare. [49-54] The fabrication of stateof-the-art microelectronics involves hightemperature processing steps, which are generally incompatible with the flexible substrates (e.g., paper, polymer, fiber, etc.) [55-61] widely used in the wearable devices. Moreover, the current microfabrication technologies are not well positioned to process the emerging functional nanomaterials (e.g., nanowires [NWs] and 2D materials). [62-65] Such incomparability severely limits the pace of deploying these emerging materials (despite their unprecedented properties) in wearable and flexible device technologies. The additive manufacturing (AM) processes have emerged as potential candidates for addressing the earlier limitations of the current microfabrication technologies in fabricating flexible/wearable printed devices with diversified functionalities, e.g., energy harvesting/storage, sensing, actuation, and computation, leveraging advantages such as maskless processing, versatile ink formulation, low cost, low processing temperature, and scalability. [66-71] Researchers have devoted tremendous efforts to develop the related technologies, and several reviews have provided excellent discussions on the material formulation and process aspects of AM techniques. [63,72-79] However, to our best knowledge, there are few review reports about the ink-based additive nanomanufacturing of functional materials for human-integrated smart wearables. To fill this gap, here we review the recent progress in ink-based

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Interfacial Rheology of Gallium-Based Liquid Metals

Cited by 85 publications

References 42 publications

A general approach to composites containing nonmetallic fillers and liquid gallium

A general approach to composites containing nonmetallic fillers and liquid gallium

Liquid Metal Direct Write and 3D Printing: A Review

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

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