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1. Controlling C2C12 Cytotoxicity on Liquid Metal Embedded Elastomer (LMEE)

   https://doi.org/10.1002/adhm.202202430  

   Won, Phillip; Coyle, Stephen; Ko, Seung Hwan; Quinn, David; Hsia, K Jimmy; LeDuc, Philip; Majidi, Carmel (July 2023, Advanced Healthcare Materials)

   Abstract Liquid metal embedded elastomers (LMEEs) are highly stretchable composites comprising microscopic droplets of eutectic gallium‐indium (EGaIn) liquid metal embedded in a soft rubber matrix. They have a unique combination of mechanical, electrical, and thermal properties that make them attractive for potential applications in flexible electronics, thermal management, wearable computing, and soft robotics. However, the use of LMEEs in direct contact with human tissue or organs requires an understanding of their biocompatibility and cell cytotoxicity. In this study, the cytotoxicity of C2C12 cells in contact with LMEE composites composed of EGaIn droplets embedded with a polydimethylsiloxane (PDMS) matrix is investigated. In particular, the influence of EGaIn volume ratio and shear mixing time during synthesis on cell proliferation and viability is examined. The special case of electrically‐conductive LMEE composites in which a percolating network of EGaIn droplets is created through “mechanical sintering” is also examined. This study in C2C12 cytotoxicity represents a first step in determining whether LMEE is safe for use in implantable biomedical devices and biohybrid systems. 

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2. 3D Highly Stretchable Liquid Metal/Elastomer Composites with Strain‐Enhanced Conductivity

   https://doi.org/10.1002/adfm.202310225  

   Fang, Ruyue; Yao, Bin; Chen, Tianwu; Xu, Xinwei; Xue, Dingchuan; Hong, Wei; Wang, Hong; Wang, Qing; Zhang, Sulin (October 2023, Advanced Functional Materials)

   Abstract Current stretchable conductors, often composed of elastomeric composites infused with rigid conductive fillers, suffer from limited stretchability and durability, and declined conductivity with stretching. These limitations hinder their potential applications as essential components such as interconnects, sensors, and actuators in stretchable electronics and soft machines. In this context, an innovative elastomeric composite that incorporates a 3D network of liquid metal (LM), offering exceptional stretchability, durability, and conductivity, is introduced. The mechanics model elucidates how the interconnected 3DLM architecture imparts softness and stretchability to the composites, allowing them to withstand tensile strains of up to 500% without rupture. The relatively low surface‐to‐volume ratio of the 3DLM network limits the reforming of the oxide layer during cyclic stretch, thereby contributing to low permanent strain and enhanced durability. Additionally, the 3D architecture facilitates crack blunting and stress delocalization, elevating fracture resistance, while simultaneously establishing continuous conductive pathways that result in high conductivity. Notably, the conductivity of the 3DLM composite increases with strain during substantial stretching, highlighting its strain‐enhanced conductivity. In comparison to other LM‐based composites featuring 0D LM droplets, the 3DLM composite stands out with superior properties. 

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3. Fabrication of Stretchable and Conductive Liquid Metal Microfibers through Coaxial Emulsion Electrospinning

   https://doi.org/10.1002/adem.202402263  

   Liu, Zihan; Ma, Jiexian; Zhang, Pu (February 2025, Advanced Engineering Materials)

   Liquid metal fibers are increasingly used in soft multifunctional materials and soft electronics due to their superb stretchability, high conductivity, and lightweight. This work presents a systematic study of the electrospinning process of liquid metal microfibers. Compared to other methods that usually produce fibers thicker than 100 μm, electrospinning is a facile and low‐cost method of producing liquid metal fibers in the range of 10–100 μm. Specifically, core‐sheath liquid metal microfibers are fabricated with a highly conductive liquid metal core and a super‐stretchable thermoplastic elastomer sheath. This manufacturing process uses a liquid metal emulsion as the core solution, which circumvents manufacturing failures caused by the high surface tension of liquid metals. The influence of key processing parameters such as core flow rate, sheath flow rate, and applied voltage on the fiber diameter and morphology is studied by experiments. The mechanical and electrical properties of the as‐fabricated liquid metal microfibers, mats, and yarns are tested and discussed. 

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4. Liquid Metal‐Vitrimer Conductive Composite for Recyclable and Resilient Electronics

   https://doi.org/10.1002/adma.202501341  

   Ho, Dong Hae; Jiang, Meng; Tutika, Ravi; Worch, Joshua C; Bartlett, Michael D (September 2025, Advanced Materials)

   Abstract Electronic devices are ubiquitous in modern society, yet their poor recycling rates contribute to substantial economic losses and worsening environmental impacts from electronic waste (E‐waste) disposal. Here, recyclable and healable electronics are reported through a vitrimer‐liquid metal (LM) microdroplet composite. These electrically conductive, yet plastic‐like composites display mechanical qualities of rigid thermosets and recyclability through a dynamic covalent polymer network. The composite exhibits a high glass transition temperature, good solvent resistance, high electrical conductivity, and recyclability. The vitrimer synthesis proceeds without the need for a catalyst or a high curing temperature, which enables facile fabrication of the composite materials. The as‐synthesized vitrimer exhibits a fast relaxation time with reconfigurability and shape memory. The electrically conductive composite exhibits high electrical conductivity with LM volume loading as low as 5 vol.%. This enables the fabrication of fully vitrimer‐based circuit boards consisting of sensors and indicator LEDs integrated with LM‐vitrimer conductive wiring. Electrical self‐healing and thermally triggered material healing are further demonstrated with the composites. The vitrimer and LM‐composite provide a pathway toward fully recyclable, mechanically robust, and reconfigurable electronics, thus advancing the field of electronic materials. 

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5. A Flexible and Electrically Conductive Liquid Metal Adhesive for Hybrid Electronic Integration

   https://doi.org/10.1002/adfm.202313567  

   Pozarycki, Tyler A; Zu, Wuzhou; Wilcox, Brittan T; Bartlett, Michael D (January 2024, Advanced Functional Materials)

   Electrical and mechanical integration approaches are essential for emerging hybrid electronics that must robustly bond rigid electrical components with flexible circuits and substrates. However, flexible polymeric substrates and circuits cannot withstand the high temperatures used in traditional electronic processing. This constraint requires new strategies to create flexible materials that simultaneously achieve high electrical conductivity, strong adhesion, and processibility at low temperature. Here, an electrically conductive adhesive is introduced that is flexible, electrically conductive (up to 3.25×10⁵S m⁻¹) without sintering or high temperature post‐processing, and strongly adhesive to various materials common to flexible and stretchable circuits (fracture energy 350 <G_c< 700 J m⁻²). This is achieved through a multiphase soft composite consisting of an elastomeric and adhesive epoxy network with dispersed liquid metal droplets that are bridged by silver flakes, which form a flexible and conductive percolated network. These inks can be processed through masked deposition and direct ink writing at room temperature. This enables soft conductive wiring and robust integration of rigid components onto flexible substrates to create hybrid electronics for emerging applications in soft electronics, soft robotics, and multifunctional systems. 

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