Boosting mechanical-to-ionic transduction for self-powered piezoionic sensing

Abstract

In the realm of sensing world, piezoionic systems have emerged as innovative tools for perceiving tactile sensations through mechanical-to-ionic transduction, mimicking biological signal production and transmission. Up to now, the biomimetic transduction mechanism and strategies to engineer the transduction efficiency remain not fully understood and underutilized. This review provides the fundamentals of mechanical-to-ionic transduction for efficient self-powered sensing, identifying the most crucial structural and operating parameters governing the generation of a transient signal output with respect to the migration and redistributions of ions upon mechanical stimulation. It also examines the recent strategies for efficiently converting mechanical keystrokes into electrical signals through performance-driven structural design, thereby maximizing piezoionic voltage generation. This involves engineering ion transport and fluid flow through porosity, microphase separation, conductive pathways and structural gradients. With respect to piezoionic effect-based applications, the review highlights the promising potential of polymeric ionic materials in soft wearable electronics, ionic skins, tissue enginereeing, biointerfaces and energy-harvesting.