Unlocking the hybrid piezo and pyroelectric nanogenerators performance by SiO2 nanowires confinement in poly(vinylidene fluoride)

TL;DR

This paper presents a novel flexible piezo/pyro-electric nanogenerator using SiO2 nanowires and PVDF, achieving significant improvements in energy harvesting efficiency through structural and electrical optimization.

Contribution

The study introduces a low-temperature fabrication method for SiO2 nanowires with PVDF infiltration, enhancing piezoelectric and pyroelectric performance in a flexible nanogenerator.

Findings

9-fold increase in piezoelectric power density

4-fold improvement in pyroelectric coefficient

Effective energy harvesting at 10-12 Hz and ΔT of 9-22 K

Abstract

We report on the development of a novel flexible piezo/pyro-electric nanogenerator (PPNG) that combines a uniform film of poly(vinylidene fluoride) (PVDF) infiltrated over vertically supported SiO2 nanowires (NWs) to enhance both piezoelectric and pyroelectric energy harvesting capabilities. The synthetic procedure involves a low-temperature multi-step approach, including the soft-template formation of SiO2 NWs on a flexible substrate, followed by the infiltration of a PVDF thin film (TF). The plasma-enabled fabrication of SiO2 NWs facilitated vertical alignment and precise control over the surface microstructure, density, and thickness of the confined nanostructures. These strategic structural systems promote the development of the most favourable electroactive \b{eta}- and {\gamma}-phases in the PVDF matrix. Notably, the electrical poling plays a major role in aligning the random dipoles of the PVDF macromolecular chain in a more ordered fashion to nucleate the amplified electroactive phases. As a proof-of-concept, the fabricated PPNG exhibited a significant improvement in the instantaneous piezoelectric output power density (P), ~ 9-fold amplification relative to its bare PVDF TF counterpart. Analogously, the pyroelectric coefficient (p) demonstrated a 4-fold superior performance with referenced PVDF TF based PPNG. Thus, the engineered system of SiO2 NWs@PVDF comprising PPNG offers a promising pathway toward multisource energy harvesting capabilities through efficient energy transduction at mechanical excitation frequencies of 10-12 Hz and across a temperature difference ({\Delta}T) of 9 to 22 K.