Puncture-resistant self-healing polymers with multi-cycle adhesion and rapid healability

The structural design of self-healing materials determines the ultimate performance of the product that can be used in a wide range of applications. Incorporating intrinsic self-healing moieties into puncture-resistant materials could significantly improve the failure resistance and product longevity, since their rapidly rebuilt bonds will provide additional recovery force to resist the external force. Herein, we present a series of tailored urea-modified poly(dimethylsiloxane)-based self-healing polymers (U-PDMS-SPs) that exhibit excellent puncture-resistant properties, fast autonomous self-healing, multi-cycle adhesion capabilities, and well-tunable mechanical properties. Controlling the composition of chemical and physical cross-links enables the U-PDMS-SPs to have an extensibility of 528% and a toughness of 0.6 MJ m(-3). U-PDMS-SPs exhibit fast autonomous self-healability with 25% strain recovery within 2 minutes of healing, and over 90% toughness recovery after 16 hours. We further demonstrate its puncture-resistant properties under the ASTM D5748 standard with an unbreakable feature. Furthermore, the multi-cycle adhesive properties of U-PDMS-SPs are also revealed. High puncture resistance (>327 mJ) and facile adhesion with rapid autonomous self-healability will have a broad impact on the design of adhesives, roofing materials, and many other functional materials with enhanced longevity.

Automated summary

The structural design of self-healing materials greatly affects their performance and application. Utilizing self-healing moieties in puncture-resistant materials improves their durability through rapidly rebuilt bonds. We present a series of tailored poly(dimethylsiloxane)-based self-healing polymers with excellent puncture resistance, fast autonomous self-healing, multi-cycle adhesion, and adjustable mechanical properties. These polymers exhibit high extensibility and toughness, fast strain and toughness recovery, puncture resistance, and multi-cycle adhesion capabilities.