ZnO nanoparticles embedded silk fibroin-a piezoelectric composite for nanogenerator applications

This paper demonstrates a flexible nanogenerator (NG) using Silk-Zinc Oxide (ZnO) composite by exploiting the inherent piezoelectric properties of silk and ZnO. A direct precipitation method was employed to synthesize Zinc Oxide nanoparticles (NPs). Silk-ZnO composite film was then prepared by spin-coating the homogenous silk-ZnO solution. The composition and morphology of silk-ZnO composite were analyzed using various standard characterization procedures. The biocompatibility study of the composite film was also performed through cell viability testing. The utility of as prepared composites was demonstrated through the fabrication of piezoelectric nanogenerator. This hybrid nanogenerator was capable to generate a maximum open circuit voltage of 25 V (peak to peak value) in the bending state for a specific ZnO concentration. The output response of the nanogenerator exhibited a good correlation with the bending angle of the device. A peak outputpower density of 6.67 mW cm(-3) was achieved from the nanogenerator. The fabricated prototype is efficient to light-up commercial red LEDs and to harvest energy from human body movement. The piezoelectric coefficient (d(33)) of silk-ZnO composite film was also experimentally figured out.

Automated summary

This paper presents a flexible nanogenerator using a Silk-Zinc Oxide (ZnO) composite. The composite is prepared by synthesizing Zinc Oxide nanoparticles and coating them onto silk to form a film. The composite exhibits good biocompatibility and adjustable piezoelectric properties, making it suitable for the fabrication of efficient nanogenerators.