Effects of particle size and oxide shell on variable stiffness performance of phase-changing materials

Buckner, Trevor L.; Farrell, Zachary; Nasab, Amir Mohammadi; Kramer‐Bottiglio, Rebecca

doi:10.1177/00219983221129252

Cited by 3 publications

(6 citation statements)

References 57 publications

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“…[ 44 ] In the case of core‐shell particles, geometrical considerations are taken into account when determining the stiffness values of particles with different sizes and shell thicknesses. [ 66 ] Assuming constant values for the elastic modulus and Poisson's ratio for the shell, the stiffness of the compressed particle should be proportional to 1/ D as observed in Figure 4b. [ 35 ]…”

Section: Resultsmentioning

confidence: 99%

Augmentation of Liquid Metal Particle Mechanics via Non‐Native Oxide Nanoshells

Kong,

Morris,

Farrell

et al. 2023

Adv Funct Materials

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Room‐temperature liquid metal particles based on gallium have become significantly important for developing next‐generation soft electronics. Eutectic gallium‐indium (EGaIn) alloys can be fabricated into core‐shell particles discretely encapsulated by a passivating oxide. Application of mechanical stimuli results in rupturing the molten core through the oxide shell, merging EGaIn particles to form conductive pathways. Generally, the mechanical properties of EGaIn are largely defined by the native oxide which imparts viscoelastic properties to the fluid. In this work, the practical implications of EGaIn deformation and fracture behavior with the native oxide and a non‐native inorganic silica shell are demonstrated. To augment the mechanical properties of EGaIn, silica nanoshells are introduced as a chemically inert coating to enable brittle fracture of particles. In situ single‐particle nanoindentation characterization reveals the environmental and geometrical considerations for particle deformation and fracture. Silica‐coated EGaIn particles reach stiffness values at least an order of magnitude higher than that of native EGaIn particles. The thickness of the silica shell can be tailored to further modify the mechanical behavior of EGaIn, enabling potential pressure‐sensitive conductivity. These results provide additional pathways to understand the design and implementation of functionalized EGaIn particles for future applications in mechanoresponsive electronics, plasmonics, and therapeutics.

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Section: Resultsmentioning

confidence: 99%

Augmentation of Liquid Metal Particle Mechanics via Non‐Native Oxide Nanoshells

Kong,

Morris,

Farrell

et al. 2023

Adv Funct Materials

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“…Bartlett et al [198] reported that by dispersing eGaIn in silicone elastomer, the value obtained from Equation ( 2) was E i = 129 kPa, but they found agreement between their experimental data and Equation ( 1) when E i = 320 kPa (Figure 4B). The difference in the elastic modulus of inclusions could be attributed to the presence of stiff oxide skin around the liquid metal inclusions, as studied by Lear et al [156] and Buckner et al, [202] and also the interaction between adjacent inclusions, which was not predicted in Eshelby's theory.…”

Section: Composites With Liquid Metal Inclusionsmentioning

confidence: 96%

“…[197] The reinforcing effect of the liquid-solid interface has been shown for single liquid-filled microcapsules [35] and also dispersed liquid inclusions in elastomers. [198][199][200][201][202][203] Style et al [196] postulated that to include the surface tension effect in the Eshelby equation for predicting composite elastic modulus E c , the liquid inclusions can be considered as soft elastic inclusions:…”

Section: Composites With Liquid Metal Inclusionsmentioning

confidence: 99%

“…[204] In this double inclusion model (Figure 4D), the elasticity of the LM inclusions is actively tuned according to the relative shell thickness of gallium oxide surrounding each inclusion, where it is known that as the size of droplets decreases the oxide shell becomes more mechanically dominant. [156,202] Bury and Koh [69] employed a microcapacitor model in their work to study the electrical behavior of multiphase composites. Therein, the composite is modeled as a network of randomly distributed microcapacitors in the host matrix.…”

Section: Composites With Liquid Metal + X Inclusionsmentioning

confidence: 99%

“…[ 197 ] The reinforcing effect of the liquid–solid interface has been shown for single liquid‐filled microcapsules [ 35 ] and also dispersed liquid inclusions in elastomers. [ 198–203 ] Style et al. [ 196 ] postulated that to include the surface tension effect in the Eshelby equation for predicting composite elastic modulus E c , the liquid inclusions can be considered as soft elastic inclusions:

\begin{equation} E_c = E\frac{1+\frac{2}{3}\frac{E_i}{E}}{(\frac{2}{3}-\frac{5\phi}{3})\frac{E_i}{E}+(1+\frac{5\phi}{3})} \end{equation}

where E i is the effective elastic modulus obtained from the properties of the dispersed and continuous phases as follows:

\begin{equation} E_i = E\frac{24\frac{\gamma}{ER}}{10+9\frac{\gamma}{ER}} \end{equation}

…”

Section: Theory and Modelingmentioning

confidence: 99%

See 2 more Smart Citations

Liquid Metal + x: A Review of Multiphase Composites Containing Liquid Metal and Other (x) Fillers

Eristoff,

Nasab,

Huang

et al. 2023

Adv Funct Materials

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Multiphase mixtures containing both liquid metal and solid inclusions in a soft polymeric matrix can exhibit unique combinations of mechanical, electrical, magnetic, and thermal properties. Gallium‐based liquid metals have excellent electrical and thermal properties, and incorporating additional conductive, magnetic, or other solid fillers into liquid metal‐embedded elastomers can yield heightened electrical and thermal conductivities, enhanced elasticity due to lowered percolation thresholds, and positive piezoconductivity. This emerging class of liquid metal + x composites, where x denotes any solid filler type, has applications in stretchable electronics, wearables, soft robotics, and energy harvesting and storage. In this review, the recent literature is consolidated on liquid metal + x composites and their potential to offer uniquely amplified or multiplied bulk properties is highlighted. The literature related to the materials and processing of liquid metal + x composites is reviewed, through which it is found that the properties of the resulting multiphase composites are sensitive to the sequence in which the distinct liquid metal and solid inclusions are incorporated into the continuous phase. This review further includes a summary of relevant predictive modeling approaches, as well as identifies grand challenges and opportunities to advance liquid metal + x composites.

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Phase Transition Liquid Metal Enabled Emerging Biomedical Technologies and Applications

Gao,

Yang,

Falchevskaya

et al. 2023

Advanced Science

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Phase change materials that can absorb or release large amounts of heat during phase transition, play a critical role in many important processes, including heat dissipation, thermal energy storage, and solar energy utilization. In general, phase change materials are usually encapsulated in passive modules to provide assurance for energy management. The shape and mechanical changes of these materials are greatly ignored. An emerging class of phase change materials, liquid metals (LMs) have attracted significant interest beyond thermal management, including in transformable robots, flexible electronics, soft actuators, and biomedicine. Interestingly, the melting point of LM is highly tunable around body temperature, allowing it to experience considerable stiffness change when interacting with human organisms during solid–liquid change, which brings about novel phenomena, applied technologies, and therapeutic methods, such as mechanical destruction of tumors, neural electrode implantation technique, and embolization therapy. This review focuses on the technology, regulation, and application of the phase change process along with diverse changes of LM to facilitate emerging biomedical applications based on the influences of mechanical stiffness change and versatile regulation strategies. Typical applications will also be categorized and summarized. Lastly, the advantages and challenges of using the unique and reversible process for biomedicine will be discussed.

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Effects of particle size and oxide shell on variable stiffness performance of phase-changing materials

Cited by 3 publications

References 57 publications

Augmentation of Liquid Metal Particle Mechanics via Non‐Native Oxide Nanoshells

Augmentation of Liquid Metal Particle Mechanics via Non‐Native Oxide Nanoshells

Liquid Metal + x: A Review of Multiphase Composites Containing Liquid Metal and Other (x) Fillers

Phase Transition Liquid Metal Enabled Emerging Biomedical Technologies and Applications

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