What question did this study set out to answer?

The aim is to develop a self-healing, flexible elastomer suitable for wearable sensors inspired by biological structures.

March 26, 2026

Multidynamic Synergistic Elastomers for Room-Temperature Self-Healing and Flexible Sensing

Key Points

The aim is to develop a self-healing, flexible elastomer suitable for wearable sensors inspired by biological structures.
Developed a polyurethane-based ion-conductive elastomer (CPU) with dynamic hydrogen bonds.
Used [EMIM][TFSI] ionic liquid to enhance properties.
Tested tensile strength, elongation, healing efficiency, and ion conductivity.
Achieved tensile strength of 15.38 MPa and elongation of 1194.18%.
Demonstrated >90% self-healing efficiency at room temperature.
Ion conductivity measured at 1.6 × 10–4 S/cm.

Abstract

Inspired by the multilayered structure and dynamic bonds of bioskin, a polyurethane (PU)-based ion-conductive elastomer (CPU) was developed by incorporating multiple dynamic hydrogen bonds into a densely cross-linked network, using EMIMTFSI ionic liquid as the conductive medium. The resulting material exhibits high strength (15.38 MPa), extreme stretchability (1194.18% elongation), autonomous room-temperature self-healing (>90% healing efficiency), and an ionic conductivity of 1.6 × 10–4 S/cm. The ionic liquid enhances chain mobility and interfacial compatibility through ion–dipole interactions, while improving dynamic behavior and preventing leakage. Leveraging these properties, the CPU was successfully applied in flexible strain sensors for sensitive and stable human motion monitoring, demonstrating significant potential for wearable electronics and smart sensing applications.

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Multidynamic Synergistic Elastomers for Room-Temperature Self-Healing and Flexible Sensing

Key Points

Abstract

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