Abstract

Flexible wearable electronics are essential for applications in healthcare, soft robotics, and human–machine interfaces. However, replicating the multifunctional capabilities of human skin—such as mechanical robustness, high elasticity, self-healing, and multimodal sensing—remains a challenge. Herein, we introduce pyridine ligands into the polymer chain segments, coordinating with Zn²⁺ ions to establish a non-covalent, cross-linked network. This structure is further integrated with ionic liquids to craft recyclable, multimodal sensing ionic elastomers. These elastomers boast robust mechanical properties with a tensile strength of 5.3?MPa and extraordinary toughness, reaching 57.9?MJ/m^?3(–|–). Additionally, they withstand up to 1400 tensile cycles. The wide sensing range of these materials—strain (5?%?80?%), pressure (2–8?kPa), and temperature (25–60?°C)—makes them ideal for tactile applications in wearable ionic skins and robotic arms. This enables real-time monitoring of both human and machine states, significantly advancing the capabilities of wearable electronics, robotics, and human–computer interfaces. The impressive performance of these ionic elastomers heralds a new era in multimodal sensing technology.