Piezoelectric polymers: theory, challenges and opportunities

Piezoelectric materials can directly transduce electrical and mechanical energy, making them attractive for applications such as sensors, actuators and energy harvesting devices. The piezoelectric effect is often associated with ceramic materials, yet piezoelectric behaviour is also observed in many polymers. The flexibility, ease of processing and biocompatibility of piezoelectric polymers mean that they are often preferable for certain applications, despite their reduced piezoelectric coefficients. This review will focus on the underlying mechanisms governing piezoelectricity in polymers from both a theoretical and practical perspective, including ways by which the effect can be enhanced through processing and structural modifications, and an outlook on specific areas in biology where piezoelectric polymers can be applied. Given that many biological materials are themselves piezoelectric, there is much interest in studying how artificial piezoelectric materials influence and stimulate cellular function. Understanding and developing piezoelectric polymers is therefore relevant for applications in energy, sensing and biology, as well as for high level, fundamental research in the physical and life sciences.