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Kirigami‐Inspired 3D‐Printable MXene Organohydrogels for Soft Electronics

Fengling Zhuo, J.B. Zhou, Ying Liu, Jianfei Xie, Hui Chen, Xiaozhi Wang, Jikui Luo, Yongqing Fu, Ahmed Elmarakbi, Huigao Duan

2023Advanced Functional Materials89 citationsDOIOpen Access PDF

Abstract

Abstract Conductive hydrogels are compelling materials for the development of soft electronics; however, their essential attributes such as high sensitivity, excellent stretchability, and environmental stability have rarely been achieved simultaneously in one hydrogel. Herein, a Kirigami‐inspired strategy is proposed to improve organohydrogel sensitivity without sacrificing their mechanical stretchability and environmental stability . The organohydrogels with multiple interpenetrating networks are synthesized by introducing sodium alginate nanofibrils and conductive MXene nanoflakes into polymer double networks infiltrated with glycerol–water mixtures, featuring remarkable stretchability (>5000%), good sensitivity, and water retention (>30 days). The Kirigami structures are further applied to enhance strain sensitivity, achieving a gauge factor of 29.1, which is ≈5.5 times that of an unstructured organohydrogel. Using the Kirigami‐inspired sensors, a durable glove is developed for grabbing underwater objects through operating a robotic arm, demonstrating a subaqueous interactive human–machine interfacing.Meanwhile, by integrating the wearable sensor with a machine learning algorithm, a wearable Morse code intelligent recognition system is demonstrated, enabling real‐time conversion of Morse code signs into speech with superior recognition accuracy (>99%) and fast response time (≈17 ms). This work offers a new route to synthesize highly sensitive, stretchable, and extremely tolerant organohydrogels, providing a promising platform for next‐generation soft electronics.

Topics & Concepts

Materials scienceSoft roboticsInterfacingSelf-healing hydrogelsWearable technologyElectronicsGauge factorNanotechnologyWearable computerSensitivity (control systems)Electrical conductorComputer scienceEmbedded systemComputer hardwareArtificial intelligenceRobotElectrical engineeringComposite materialFabricationElectronic engineeringAlternative medicineEngineeringPathologyPolymer chemistryMedicineAdvanced Sensor and Energy Harvesting MaterialsAdvanced Materials and MechanicsMXene and MAX Phase Materials