Self-healing structures mimic the ability of biological structures (e.g. bone) to redistribute their structural mass in response to dynamic service loads and damaging effects. The self-healing features yield enhanced levels of structural efficiency and safety in dynamic service environments. In this study, the piezoelectric effect was used to convert the dynamic mechanical energy applied to the structure into electrical energy that, in turn, was used to drive electrochemical self-healing phenomena within a solid electrolyte. A theoretical framework was developed for self-healing materials, and experiments were conducted to verify the fundamental principles of the approach. The theoretical models confirmed that: (1) the piezoelectric effect can, within the geometric and mechanical constraints of actual structural systems, generate sufficient electric potential and charge (through harvesting the available mechanical energy) to enable electrochemical mass transport within a solid electrolyte; and (2) the redistribution of structural mass in dynamic service environments can occur within viable time frames. The fundamental principles of the new self-healing materials were validated through the demonstration of piezo-induced electrolytic phenomena in solid electrolytes and by verifying the gains in mechanical performance associated with such phenomena.
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