Increasing Permittivity and Mechanical Harvesting Response of PVDF-Based Flexible Composites by Using Ag Nanoparticles onto BaTiO 3 Nanofillers.
Nadejda HorchidanCristina Elena CiomagaLavinia Petronela CurecheriuGeorge StoianMihaela BoteaMihaela FloreaValentin Adrian MaraloiuLucian PintilieFlorin Mihai TufescuVasile TironAurelian RotaruLiliana MitoseriuPublished in: Nanomaterials (Basel, Switzerland) (2022)
The role of Ag addition on the structural, dielectric, and mechanical harvesting response of 20%( x Ag - (1 - x )BaTiO 3 ) - 80%PVDF ( x = 0, 2, 5, 7 and 27 vol.%) flexible composites is investigated. The inorganic fillers were realized by precipitating fine (~3 nm) silver nanoparticles onto BaTiO 3 nanoparticles (~60 nm average size). The hybrid admixtures with a total filling factor of 20 vol.% were embedded into the PVDF matrix. The presence of filler enhances the amount of β-PVDF polar phase and the BaTiO 3 filler induces an increase of the permittivity from 11 to 18 (1 kHz) in the flexible composites. The addition of increasing amounts of Ag is further beneficial for permittivity increase; with the maximum amount ( x = 27 vol.%), permittivity is three times larger than in pure PVDF (εr ~ 33 at 1 kHz) with a similar level of tangent losses. This result is due to the local field enhancement in the regions close to the filler-PVDF interfaces which are additionally intensified by the presence of silver nanoparticles. The metallic addition is also beneficial for the mechanical harvesting ability of such composites: the amplitude of the maximum piezoelectric-triboelectric combined output collected in open circuit conditions increases from 0.2 V/cm 2 (PVDF) to 30 V/cm 2 for x = 27 vol.% Ag in a capacitive configuration. The role of ferroelectric and metallic nanoparticles on the increasing mechanical-electric conversion response is also been explained.