Liquid Metal Droplets Wrapped with Polysaccharide Microgel as Biocompatible Aqueous Ink for Flexible Conductive Devices

Li, Xiankai; Li, Mingjie; Zong, Lu; Wu, Xiaochen; You, Jun; Du, Peikang; Li, Chaoxu

doi:10.1002/adfm.201804197

Cited by 198 publications

(206 citation statements)

References 39 publications

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“…Nanosized distribution in bulk solids has been very difficult for liquid metals due to their unique physical interfacial energy. [22] As shown in Figure 3b (Figure 3c), which exhibited heavily phase separation in 1 h. [8] Transmission electron micro scopy (TEM) image of the LM colloidal solution (Figure S11, Supporting Information) showed that the polysulfide loops and thiol groups in sulfur polymers significantly helped the dispersion of liquid metals in solution, achieving an average size as small as 82 nm, similar as previous reports. [31][32][33][34][35] In this work, ring-opening polymerization and inverse vulcanization of elemental sulfur offer sufficient polysulfide loops and thiol ligand (Scheme S1; Figure 2b,c) to disperse the liquid metals.…”

Section: Introductionsupporting

confidence: 84%

“…[15,17] The polysulfide loops (R-S n -R) and thiol terminal groups (R-SH) are both very effective ligands to stabilize liquid metals in solution as reported by previous references (Figure 3a). [8,9] The X-ray photoelectron spectroscopy (XPS) spectra (Figure 3d; Figure S13, Supporting Information) for liquid metals collected from LMESP-50% solution showed peaks of Ga 2d, Ga 3d, In 3d, O 1s, C 1s, and S 2p, indicating the coating (binding) of sulfur polymers on LM. [22] As shown in Figure 3b (Figure 3c), which exhibited heavily phase separation in 1 h. [8] Transmission electron micro scopy (TEM) image of the LM colloidal solution (Figure S11, Supporting Information) showed that the polysulfide loops and thiol groups in sulfur polymers significantly helped the dispersion of liquid metals in solution, achieving an average size as small as 82 nm, similar as previous reports.…”

Section: Introductionmentioning

confidence: 99%

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Ultrauniform Embedded Liquid Metal in Sulfur Polymers for Recyclable, Conductive, and Self‐Healable Materials

Xin

Peng

et al. 2019

Adv Funct Materials

180

143

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Liquid metals (LMs) are receiving growing interest in modern technologies for their various advantages. This work reports using elemental sulfur to achieve nanodispersed liquid metals in bulk polymers for multifunctional LM-based materials. Ring-opening polymerization and inverse vulcanization of elemental sulfur provide many polysulfide loops and thiol groups as effective binding ligands that enable extraordinarily uniform dispersion of liquid metals (≈1 µm) in bulk matrix and improve the mechanical performance of the materials. Interestingly, the liquid-metal-embedded sulfur polymer (LMESP) materials exhibit excellent thermal-/solventprocessability and recyclability. The uniform dispersion leads to phenomenal electrical conductivity of the LMESP at a low volume percentage of LM (30 vol%), overcoming the issue of nonconductivity typically seen in insulated LM-polymer blends. Additionally, the LMESP shows resistive sensitivity toward external pressure. Furthermore, the LMESP materials exhibit an excellent self-healing ability under mild conditions via the dynamic bonds between polysulfide loops/thiol groups and liquid metals. This work clearly offers a new platform to design liquid metals and can push them for broad applications.

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Section: Introductionsupporting

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Ultrauniform Embedded Liquid Metal in Sulfur Polymers for Recyclable, Conductive, and Self‐Healable Materials

Xin

Peng

et al. 2019

Adv Funct Materials

180

143

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“…This approach has been well‐studied and the resulting colloidal solution was employed as conductive ink for soft and flexible electronics . Stable aqueous suspensions of LM nanodroplets are not only for electronic applications, but also exhibit great potential in medicine and therapy, such as drug delivery, photothermal therapy, and bioimaging . Water‐soluble surfactants, including cetrimonium bromide, poly(4‐vinyl‐1‐methyl‐pyridinium bromide), lysozyme, and trithiocarbonate‐functionalized brushed polyethylene glycol have been used to stabilize LM nanodroplets during and after sonication of bulk LMs in water .…”

mentioning

confidence: 99%

“…Water‐soluble surfactants, including cetrimonium bromide, poly(4‐vinyl‐1‐methyl‐pyridinium bromide), lysozyme, and trithiocarbonate‐functionalized brushed polyethylene glycol have been used to stabilize LM nanodroplets during and after sonication of bulk LMs in water . In addition, when LM nanodroplets in aqueous solution are placed at room temperature for 16 h or heated up to about 70 °C for 30 min, the spherical nanodroplets will be oxidized and dealloyed, resulting in the formation of rods of gallium oxide monohydroxide (GaOOH) and spherical indium nanoparticles . To overcome this issue, various polymer coatings were used to inhibit the oxidation of LM nanodroplets and stabilize them .…”

mentioning

confidence: 99%

Light‐Induced Shape Morphing of Liquid Metal Nanodroplets Enabled by Polydopamine Coating

Gan

Shang

Handschuh‐Wang

et al. 2019

Small

105

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Shape morphing nanosystems have recently attracted much attention and a number of applications are developed, spanning from autonomous robotics to drug delivery. However, the fabrication of such nanosystems remains at an early stage owing to limited choices of strategies and materials. This work reports a facile method to fabricate liquid metal (LM) nanodroplets by sonication of bulk LM in an aqueous dopamine hydrochloride solution and their application in light‐induced shape morphing at the nanoscale. In this method, dopamine acts as a surfactant, which stabilizes the LM nanodroplets dispersion during the sonication, and results in downsizing of the nanodroplets. Furthermore, by adding 2‐amino‐2‐(hydroxymethyl)‐1,3‐propanediol to the suspension, self‐polymerization of dopamine molecules occurs, resulting in the formation of polydopamine (PDA)‐coated LM nanodroplets. Owing to the high photothermal conversion of the PDA, PDA‐coated LM nanodroplets are transformed from spherical shapes to ellipsoids by NIR laser irradiation. This study paves a simple and reliable pathway for the preparation of functional LM nanodroplets and their application as shape‐morphing nanosystems.

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“…), which is enabled to slightly elongate but it is also limited. [20][21][22][23][24][25] In their methods, the liquid metal has been designed into functional conductive structure by taking advantage of own liquid characteristic. [15,16] Unlike these traditional conductive rigid materials, the emerging galliumbased liquid metals with advantages of low Young's moduli (1)(2)(3)(4)(5)(6)(7)(8)(9)(10) and in principle infinitely deformable have attracted great attention as an ideal candidate for fabricating stretchable conductive pattern.…”

mentioning

confidence: 99%

A Novel Strategy for Preparing Stretchable and Reliable Biphasic Liquid Metal

Deng

Peng

et al. 2019

Adv Funct Materials

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Low-melting liquid metal is a hugely promising material for flexible conductive patterns due to its excellent conductivity and supercompliance, especially low-cost and environmental liquid processing technology. However, the ever-present fluidity characteristic greatly limits the stable shape and reliability of prepared liquid metal conductive electronics. Herein, a novel solidification strategy of liquid GaIn alloys by Ni doping and heat treatment is first reported, which can efficiently create a solid phase in the liquid metal and provide an effective solution for practical applications. Particularly, the liquid characteristic is preserved for conveniently fabricating different flexible electronic circuits, and then the solidification is carried out on prepared conductive patterns by heat treatment. The solidification mechanism is revealed by the interface chemical reaction between Ni and GaIn, creating the solid phase of intermetallic compound (Ga 4 Ni 3 and InNi 3 ) during heat treatment. Moreover, a biphasic GaInNi can be obtained by regulating the atomic ratio of gallium, indium, and nickel. As a result, the obtained GaInNi possesses extremely low sheet resistance (15 ± 4.5 to 135 ± 2.5 mΩ sq −1 ) and the variation of ΔR/R 0 exhibits low level (0-2) when strained up to 100%, which offers a promising strategy to prepare stretchable and reliable liquid metal electronics.

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Liquid Metal Droplets Wrapped with Polysaccharide Microgel as Biocompatible Aqueous Ink for Flexible Conductive Devices

Cited by 198 publications

References 39 publications

Ultrauniform Embedded Liquid Metal in Sulfur Polymers for Recyclable, Conductive, and Self‐Healable Materials

Ultrauniform Embedded Liquid Metal in Sulfur Polymers for Recyclable, Conductive, and Self‐Healable Materials

Light‐Induced Shape Morphing of Liquid Metal Nanodroplets Enabled by Polydopamine Coating

A Novel Strategy for Preparing Stretchable and Reliable Biphasic Liquid Metal

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