Microstructure Dependence of Output Performance in Flexible PVDF Piezoelectric Nanogenerators

Flexible piezoelectric nanogenerators have attracted great attention due to their ability to convert ambient mechanical energy into electrical energy for low-power wearable electronic devices. Controlling the microstructure of the flexible piezoelectric materials is a potential strategy to enhance the electrical outputs of the piezoelectric nanogenerator. Three types of flexible polyvinylidene fluoride (PVDF) piezoelectric nanogenerator were fabricated based on well-aligned nanofibers, random oriented nanofibers and thick films. The electrical output performance of PVDF nanogenerators is systematically investigated by the influence of microstructures. The aligned nanofiber arrays exhibit highly consistent orientation, uniform diameter, and a smooth surface, which possesses the highest fraction of the polar crystalline beta phase compared with the random-oriented nanofibers and thick films. The highly aligned structure and the large fraction of the polar beta phase enhanced the output performance of the well-aligned nanofiber nanogenerator. The highest output voltage of 14 V and a short-circuit current of 1.22 mu A were achieved under tapping mode of 10 N at 2.5 Hz, showing the potential application in flexible electronic devices. These new results shed some light on the design of the flexible piezoelectric polymer-based nanogenerators.

Automated summary

Controlling the microstructure of flexible piezoelectric materials enhances the electrical output performance of nanogenerators, with the best results achieved in well-aligned nanofiber arrays. This research sheds light on the potential application of flexible piezoelectric polymer-based nanogenerators in wearable electronic devices.