Super‐Elastic and Temperature‐Tolerant Hydrogel Electrodes for Supercapacitors via MXene Enhanced Ice‐Templating Synthesis

Abstract

AbstractDeveloping flexible energy storage devices with good deformation resistance under extreme operating conditions is highly desirable yet remains very challenging. Super‐elastic MXene‐enhanced polyvinyl alcohol/polyaniline (AMPH) hydrogel electrodes are designed and synthesized through vertical gradient ice templating‐induced polymerization. This approach allows for the unidirectional growth of polyaniline (PANI) and 2D MXene layers along the elongated arrayed ice crystals in a controlled manner. The resulting 3D unidirectional AMPH hydrogel exhibits inherent stretchability and electronic conductivity, with the ability to completely recover its shape even under extreme conditions, such as 500% tensile strain, 50% compressive strain. The presence of MXene in the hydrogel electrode enhances its resilience to mechanical compression and stretching, resulting in less variation in resistance. AMPH has a specific capacitance of 130.68 and 88.02 mF cm−2 at a current density of 0.2 and 2 mA cm−2, respectively, and retains 90% and 70% of its original capacitance at elongation of 100% and 200%, respectively. AMPH‐based supercapacitors demonstrate exceptional performance in high salinity environments and wide temperature ranges (−30–80 °C). The high electrochemical activity, temperature tolerance, and mechanical robustness of AMPH‐based supercapacitor endow it promising as the power supply for flexible and wearable electronic devices.