Strategies to Enhance ZnO Nanogenerator Performance via Thermal-Annealing and Cryo-Cooling

TL;DR

This study explores how thermal-annealing and cryo-cooling post-treatments improve the performance of ZnO nanogenerators by enhancing nanowire quality and structural properties, leading to higher energy harvesting efficiency.

Contribution

It introduces a simple, effective approach combining nanowire growth with post-growth cryo-cooling to significantly boost nanogenerator performance.

Findings

Cryo-cooling yields superior nanogenerator performance compared to annealing.

Post-treatment improves nanowire crystallinity and alignment.

Enhanced energy output demonstrates potential for smart device integration.

Abstract

Piezoelectric capacitive NanoGenerators (NG) based on vertically grown crystalline zinc oxide nanowires (ZnO-NWs) have been fabricated using a low-cost and scalable hydrothermal method on gold-coated silicon substrates, which served as both a seed layer and a conductive bottom electrode. Morphological and structural characterizations demonstrate that the obtained ZnO NWs are dense, uniformly distributed, vertically well aligned and exhibit good crystal quality. The piezoelectric NG consists of ZnO-NWs grown on a gold-coated silicon substrate, parylene-C matrix, titanium/aluminium top electrode and poly(dimethylsiloxane) (PDMS) encapsulating layer. In order to enhance the NG performances, which is the main goal of this study, two distinctly different post-growth treatments, namely thermal annealing in ambient air and cryo-cooling by immersion in liquid nitrogen, are applied and their effect studied. Achieving the high performance of NG via the combination of high-quality NWs growth and subsequent post-growth treatment is presented. Superior global performance of NG has been observed with a post-treatment of cryo-cooling for an optimum duration compared to the thermal annealing signifies the simplicity and novelty of the work. The proposed strategies highlight the role of post-growth treatments towards the fabrication of high-performance functional NG to be incorporated into future smart objects.