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| Naji, M. |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Casati, R. |
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| Kočí, Jan | Prague |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Azevedo, Nuno Monteiro |
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Taylor, John
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Publications (12/12 displayed)
- 2018Freeze cast porous barium titanate for enhanced piezoelectric energy harvestingcitations
- 2018Corrigendum to “Modelling and fabrication of porous sandwich layer barium titanate with improved piezoelectric energy harvesting figures of merit” [Acta Mater. 128 (2017) 207–217](S1359645417301209)(10.1016/j.actamat.2017.02.029)citations
- 2017Modelling and fabrication of porous sandwich layer barium titanate with improved piezoelectric energy harvesting figures of meritcitations
- 2016Inexpensive and fast pathogenic bacteria screening using field-effect transistorscitations
- 2016Manufacture and characterization of porous ferroelectrics for piezoelectric energy harvesting applicationscitations
- 2014Manufacturing and characterization of Magnéli phase conductive fibrescitations
- 2013Hot tear susceptibility of Al-Mg-Si alloys with varying iron contentscitations
- 2012AC electrical properties of TiO2 and Magnéli phases, TinO2n−1citations
- 2011Impedance spectroscopy analysis of Ti n O 2n-1 Magnéli phasescitations
- 2011Impedance spectroscopy analysis of TinO2n-1 Magnéli phasescitations
- 2010Nanostructured electrodes for biocompatible CMOS integrated circuitscitations
- 2009Formation of a porous alumina electrode as a low-cost CMOS neuronal interfacecitations
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article
Freeze cast porous barium titanate for enhanced piezoelectric energy harvesting
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 . The freeze cast barium titanate with 45 vol.% porosity had a d 33 = 134.5 pC N -1 compared to d 33 = 144.5 pC N -1 for dense barium titanate. The d 33 coefficients of the freeze cast materials were also higher than materials with uniformly distributed spherical porosity due to improved poling of the aligned microstructures, as predicted by the models. 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 pm 2 N -1 for barium titanate with 45 vol.% porosity, compared to only 1.40 pm 2 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.