Litcius/Paper detail

Tough Conductive Organohydrogel for Wearable Sensing in Extreme Environmental Conditions

Seokkyoon Hong, Taewoong Park, Junsang Lee, Yuhyun Ji, Yumin Dai, Jonghun Yi, Joshua Jeremiah Kim, Dong Rip Kim, Chi Hwan Lee

2023Advanced Materials Technologies10 citationsDOI

Abstract

Abstract Conductive hydrogels, despite their significant potential, have faced historical limitations including vulnerability to dehydration, degradation of performance at extreme temperatures, and susceptibility to freezing in subzero conditions. Furthermore, the development of hydrogels that are both tough and stretchable, capable of maintaining performance under extreme environmental conditions, has remained a challenging task. Herein, an innovative conductive organohydrogel, distinguished by its superior toughness, stretchability, stability in regular ambient conditions, vacuum adaptability, and resistance to extreme temperatures is presented. By implementing a unique dry annealing process during synthesis, the mechanical strength of the organohydrogel has been substantially enhanced, dehydration concerns have been alleviated, and the structural integrity has been reinforced. In addition, the composition of the organohydrogel is specifically engineered to achieve both lasting endurance and sustainable longevity. This study signifies a crucial leap forward in creating high‐performing organohydrogels capable of functioning in a wide range of environments and conditions, thereby unlocking an array of adaptable applications.

Topics & Concepts

Self-healing hydrogelsMaterials scienceToughnessAdaptabilityElectrical conductorWearable computerExtreme heatNanotechnologyComputer scienceComposite materialEmbedded systemEcologyClimate changeBiologyPolymer chemistryAdvanced Sensor and Energy Harvesting MaterialsConducting polymers and applicationsAdvanced Materials and Mechanics