The class of smart materials known as Self-Healing Polymers is revolutionising how we think about durability, maintenance and longevity in engineered systems. These autonomous repair polymers are designed to detect and repair micro-damage—such as cracks or delamination—either through built-in dynamic bonds or embedded healing agents, restoring structural integrity without external intervention. Unlike conventional polymers, which degrade over time due to fatigue, environmental stressors or mechanical damage, self-healing polymers can autonomously respond to such stress by triggering reversible chemical reactions (e.g., Diels–Alder chemistry, disulfide exchange) or reactivating physically reversible networks (e.g., hydrogen bonds or supramolecular crosslinks). These mechanisms allow the material to recover lost properties — like toughness, conductivity or elasticity — thereby extending service life and reducing maintenance needs. 

In practical applications, self-healing polymers provide significant value in sectors where long-term reliability is critical: automotive, aerospace, electronics, coatings and infrastructure. For instance, in automotive components, self-healing elastomers can recover from micro-tears or fatigue cracks, improving crashworthiness and reducing costly repairs. In electronics, they help restore conductivity and mechanical cohesion after damage, while in coatings, these materials can reseal minor abrasions or scratches, protecting the substrate beneath. Recent developments have pushed boundaries even further: researchers have demonstrated self-healing materials that rapidly recover from damage, even under ambient conditions, without requiring heat or external catalysts. Such innovations open doors to more resilient, longer-lasting materials that adapt and heal much like biological tissue — ultimately making products safer, more reliable and more sustainable.