AI Article Synopsis
- Conductive organohydrogels have potential for use in strain sensors, but their applications are hindered by weak mechanical properties and unstable long-term performance.
- A new method called solvent exchange assisted hot-pressing enhances the strength, toughness, and fatigue resistance of ionically conductive organohydrogels (ICOHs).
- ICOHs show impressive mechanical attributes like tensile strength of 36.12 MPa and can withstand 10,000 cycles without crack propagation, making them ideal for wearable and durable electronics.
Article Abstract
Conductive organohydrogels are promising for strain sensing, while their weak mechanical properties, poor crack propagation resistance and unstable sensing signals during long-term use have seriously limited their applications as high-performance strain sensors. Here, we propose a facile method, , solvent exchange assisted hot-pressing, to prepare strong yet tough, transparent and anti-fatigue ionically conductive organohydrogels (ICOHs). The densified polymeric network and improved crystallinity endow ICOHs with excellent mechanical properties. The tensile strength, toughness, fracture energy and fatigue threshold of ICOHs can reach 36.12 ± 4.15 MPa, 54.57 ± 2.89 MJ m, 43.44 ± 8.54 kJ m and 1212.86 ± 57.20 J m, respectively, with a satisfactory fracture strain of 266 ± 33%. In addition, ICOH strain sensors with freezing and drying resistance exhibit excellent cycling stability (10 000 cycles). More importantly, the fatigue resistance allows the notched strain sensor to work normally with no crack propagation and output stable and reliable sensing signals. Overall, the unique flaw-insensitive strain sensing makes ICOHs promising in the field of wearable and durable electronics.
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| http://dx.doi.org/10.1039/d4mh00740a | DOI Listing |
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