# Freeze cast porous barium titanate for enhanced piezoelectric energy   harvesting

**Authors:** J. I. Roscow, Y. Zhang, M. J. Kra\'sny, R. W.C. Lewis, J. Taylor, C., R. Bowen

arXiv: 1902.00314 · 2019-02-04

## TL;DR

This study enhances piezoelectric energy harvesting by creating highly aligned porous barium titanate through freeze casting, significantly improving energy conversion efficiency and demonstrating both modeling and experimental validation.

## Contribution

It introduces a novel freeze casting method to produce aligned porous barium titanate with superior energy harvesting performance, supported by comprehensive modeling and experimental results.

## Key findings

- Porous barium titanate shows a 2.4-fold increase in energy harvesting voltage.
- Introduction of porosity reduces permittivity and increases energy harvesting figure of merit.
- Model predictions align well with experimental measurements.

## Abstract

Energy harvesting is an important developing technology for a new generation of self-powered sensor networks. This paper demonstrates the significant improvement in the piezoelectric energy harvesting performance of barium titanate by forming highly aligned porosity using freeze casting. Firstly, a finite element model demonstrating the effect of pore morphology and angle with respect to poling field on the poling behaviour of porous ferroelectrics was developed. A second model was then developed to understand the influence of microstructure-property relationships on the poling behaviour of porous freeze cast ferroelectric materials and their resultant piezoelectric and energy harvesting properties. To compare with model predictions, porous barium titanate was fabricated using freeze casting to form highly aligned microstructures with excellent longitudinal piezoelectric strain coefficients, d 33. Both model and experimental data indicated that introducing porosity provides a large reduction in the permittivity () of barium titanate, which leads to a substantial increase in energy harvesting figure of merit, , with a maximum of 3.79 pm2 N-1 for barium titanate with 45 vol.% porosity, compared to only 1.40 pm2 N-1 for dense barium titanate. Dense and porous barium titanate materials were then used to harvest energy from a mechanical excitation by rectification and storage of the piezoelectric charge on a capacitor. The porous barium titanate charged the capacitor to a voltage of 234 mV compared to 96 mV for the dense material, indicating a 2.4-fold increase that was similar to that predicted by the energy harvesting figures of merit.

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Source: https://tomesphere.com/paper/1902.00314