期刊
MATERIALS TODAY COMMUNICATIONS
卷 28, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.mtcomm.2021.102528
关键词
Energy harvesting; Piezoelectric Nanogenerator; Polyvinylidene fluoride
资金
- 3rd Programme d'Investissements d'Avenir [ANR-18-EUR-0006-02]
- TOTAL
- French National Research Agency (ANR), Investissements d'Avenir program (Labex NanoSaclay) [ANR-10-LABX-0035]
- French Network EMIR
- Chair Challenging Technology for Responsible Energy
Piezoelectric PVDF polymer thin films are nanostructured by swift heavy ion beam to create nanoporous structures, then partially filled with Ni(0) to form a composite with higher dielectric permittivity. Subsequent electron beam irradiation induces chain scissions in the PVDF matrix, resulting in increased flexibility without affecting remanent polarization. The optimized energy harvesting properties are achieved with 1MGy irradiation, delivering an output voltage of 4.1 V.cm(-2) and a maximum output power of 25 mu W. cm(-2). The mechanisms responsible for enhanced harvesting efficiency due to electron beam irradiation are discussed.
Piezoelectric PVDF polymer thin films are nanostructured by swift heavy ion beam resulting in nanoporous structures. The nanocylindars are then partially filled with Ni(0) in order to create a composite of higher dielectric permittivity. In a second step, the composite is irradiated with electron beam, in order to induce chain scissions in the PVDF matrix and render it more flexible. It is found that e-beam irradiation does not affect the remanent polarization up to more than 1MGy. The energy harvesting properties are optimized with a maximum for 1MGy irradiation, delivering an output voltage of 4.1 V.cm(-2) which corresponds to a maximum output power of 25 mu W. cm(-2) and an integrated power of 0.46 mu W. cm(-2) for 1 bar of external pressure (mechanical solicitations frequency of 10 Hz). The mechanisms responsible for the enhancement of the harvesting efficiency due to e-beam irradiation are discussed.
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