Facile Synthesis of Ultratough Conductive Gels with Swelling and Freezing Resistance for Flexible Sensor Applications (一作,中科院二區(qū),scientific-reports,IF=3.8)
作者:Pengpeng Lu1, 2, Jingyang Xu3, Shuyan Liu3, Lili Fu3, Shengxian Wu1, Ze Liu1, Tu Hou2, He Liu1, 2*,
關(guān)鍵字:Flexible Sensor, Swelling and Freezing Resistance, Ultratough Conductive Gels
論文來(lái)源:期刊
發(fā)表時(shí)間:2025年
The application of flexible hydrogel sensors in extreme environments, such as low temperatures, underwater, or significant mechanical deformations, poses considerable challenges. Conventional approaches to developing ultra-tough, swelling- and freezing-resistant conductive gels typically rely on complex molecular modifications or the incorporation of external conductive and freeze-resistant fillers. Here, we present a simple one-pot method to fabricate ultra-tough, swelling- and freezing-resistant conductive organohydrogels without external conductive and freeze-resistant fillers. During gelation, by-products (C?H??NHCl, KCl) provide both conductivity and antifreeze properties, thus eliminating compatibility issues and dispersion challenges associated with external fillers. The resulting gel exhibits super toughness, with tensile strength reaching 10.2 MPa and stretchability up to 800% in the dry state. Following covalent crosslinking, the gel demonstrates excellent anti-swelling properties, with a swelling ratio of only 15.4% after 24 h of water immersion, while maintaining a tensile strength of 5.8 MPa and an elongation of up to 1000%. When fabricated into flexible sensors, these gels display stable electrical responsiveness and desired Gauge Factor (0.58-2.25), effectively detecting limb movements. Furthermore, the gel's superior resistance to freezing and swelling ensures reliable signal stability under both -20 °C and underwater conditions. These combined properties render the conductive gel a promising candidate for flexible sensing components in robotic and bionic applications.