Flexible electronics have been rapidly advancing and have garnered significant interest in monitoring physiological activities and health conditions. However, flexible electronics are prone to detachment in humid environments, so developing human-friendly flexible electronic devices that can effectively monitor human movement under various aquatic conditions and function as flexible electrodes remains a significant challenge. Here, we report a strongly adherent, self-healing, and swelling-resistant conductive hydrogel formed by combining the dual synergistic effects of hydrogen bonding and dipole-dipole interactions. The hydrogel has a commendable linear operating range (∼200% strain, GF = 1.44), stability of electrical signals for 200 cycles, excellent conductivity (2.18 S m-1), self-healing properties (∼30 min), and durable underwater adhesion stability. The conductive hydrogel can be developed into a flexible electronic sensor for detecting motion signals, such as joint flexion and swallowing, as well as for real-time underwater communication using Morse code. Additionally, the integration of this polymer with a low contact impedance facilitates real-time, high-fidelity detection of electroencephalogram (EEG) signals, serving as a flexible electrode. It is believed that our hydrogel will have good prospects in future wearable electronics.
Keywords: EEG electrode; conductive hydrogel; self-healing; strain sensor; tannic acid; wet adhesion.