Litcius/Paper detail

Highly Permeable and Ultrastretchable Liquid Metal Micromesh for Skin-Attachable Electronics

Xiaohui Ma, Menghu Zhang, Jiaxue Zhang, Shaolei Wang, Shitai Cao, Yanyan Li, Gaohua Hu, Desheng Kong

2022ACS Materials Letters67 citationsDOI

Abstract

Stretchable electronics represents an emerging technology for next-generation smart wearables toward intimate integration with the human body. In contrast with functional devices constructed over elastomer films with limited moisture permeability, a soft electronic textile may represent the ideal skin-attachable platform to achieve long-term wearing comfort. The advancements in this active area largely hinge on a new generation of permeable conductor. Despite its intrinsic mechanical deformability, gallium-based liquid metal typically represents an impenetrable barrier for gases and liquids. In this study, we introduce a liquid metal micromesh on electrospun microfiber textile as a highly permeable and ultrastretchable conductor. The fabrication process involves dropcasting liquid metal onto an elastomeric microfiber textile followed by high-speed rotation to remove the excessive coating. The liquid metal micromesh exhibits low sheet resistance (0.38 Ω/sq), ultrahigh stretchability (>1000% strain), and mechanical durability. The porous morphology enables a high steam permeability and perception of comfort comparable to those of standard textiles. The conformal interface with the skin gives rise to low contact impedance better than that of state-of-the-art Ag/AgCl gel electrodes. The successful implementation of the liquid micromesh conductor in a multifunctional electronic system demonstrates its practical suitability for a broad range of applications in stretchable and wearable electronics.

Topics & Concepts

Materials scienceStretchable electronicsLiquid metalElastomerElectronicsMicrofiberNanotechnologyComposite materialWearable technologyFabricationWearable computerElectrical engineeringComputer scienceAlternative medicineEngineeringEmbedded systemMedicinePathologyAdvanced Sensor and Energy Harvesting MaterialsConducting polymers and applicationsTactile and Sensory Interactions