Journal
ENERGY & ENVIRONMENTAL SCIENCE
Volume 13, Issue 3, Pages 868-883Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/c9ee03059j
Keywords
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Funding
- Australian Government through the Australian Research Council [LP160100071, FT130100211]
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With an increasing global energy demand, along with a rising uptake of portable electronic devices, it is of great importance to investigate the viability of alternative energy harvesting technologies. Flexible piezoelectric generators (PEGs) are able to convert mechanical energy to electricity, making them an idea[ candidate to decrease reliance on conventional energy sources and to power flexible, portable and implantable electronics. In this study, we show a [ow -energy production pathway for transparent PEGs based on poly(vinylidene fluoride-co-trif[uoroethy[ene) (PVDF-TrFE) via shear -induced alignment of its dipoles through extrusion printing, complemented by spatial dipolar tempEating onto single -walled carbon nanotubes (SWCNTs) at [ow concentrations (<0.05 wt%). The resulting composite PEGs show up to a 500% enhancement in the piezoelectric charge coefficient d33 relative to extrusion printed pristine PVDF-TrFE, with similar enhancements in energy harvesting, exhibiting a power density of up to 20 W cm(-3) at 0.02 wt% SWCNTs. The extrusion printed composite PEGs show recyc[abi[ity using only a green solvent (acetone) and are found to exhibit piezoelectric energy harvesting with a power density of up to 71 W cm(-3) upon reprinting, overcoming two of the most significant hurdles towards commercial production of flexible PEGs.
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