Determining the most efficient geometry through simulation study of ZnO nanorods for the development of high-performance tactile sensors and energy harvesting devices

TL;DR

This study uses simulation to identify the optimal geometry and inclination of ZnO nanorods for maximizing piezoelectric output in sensors and energy harvesters, revealing inclined nanorods outperform vertical ones.

Contribution

It introduces a simulation-based analysis of various ZnO nanorod geometries and orientations, highlighting the superior performance of inclined nanorods for piezoelectric applications.

Findings

Inclined ZnO nanorods produce higher piezoelectric output than vertical ones.

Optimal inclination at 60 degrees yields approximately 215 mV output.

Simulation results challenge the assumption that vertical nanorods are always best.

Abstract

The piezoelectric nanomaterial ZnO exhibits an excellent piezoelectric response that can transduce mechanical energy into electrical signals by applying pressure. The piezoelectric behavior of ZnO nanostructures (especially nanorods or microrods) is getting considerable attention in the fabrications of piezo tactile sensors, energy harvesting devices, and other self-powering implantable devices. Especially vertically aligned ZnO nanorods are of high interest due to their higher value of piezoelectric coefficient along the z-direction. In this report, various geometries and alignments of ZnO nanorods are explored and their effect on strength of piezoelectric output potential has been simulated by COMSOL Multiphysics software. Best suited geometry and inclination are explored in this simulation to achieve high piezoelectric output in haptic and energy harvester devices. The simulation results show out of many geometries and inclinations the highest piezoelectric output is demonstrated by the inclined ZnO nanorods due to the application of higher torque force or shear stress in similar applied force. The high torque force or shear stress at 60 degree orientation and optimized contributions from all the piezoelectric coefficients resulted in a high piezoelectric output potential close to 215 mV which is much higher than the vertically aligned ZnO nanorod which is approximately 25 mV. The results are contrary to the accepted understanding that the vertical ZnO nanorods should produce the highest output voltage due to the high piezoelectric coefficient along the z-axis.