Abstract
This work aimed to study the influence of the hybrid interface in polyvinylidene fluoride (PVDF)-based composite thin films on the local piezoelectric response. Our results provide evidence of a surprising contradiction: the optimization process of the β-phase content using nano-inclusions did not correspond to the expected nanoscale piezoelectric optimization. A large piezoelectric loss was observed at the nanoscale level, which contrasts with the macroscopic polarization measurement observations. Our main goal was to show that the dispersion of metallic ferromagnetic nano-inclusions inside the PVDF films allows for the partial recovery of the local piezoelectric properties. From a dielectric point of view, it is not trivial to expect that keeping the same amount of the metallic volume inside the dielectric PVDF matrix would bring a better piezoelectric response by simply dispersing this phase. On the local resonance measured by PFM, this should be the worst due to the homogeneous distribution of the nano-inclusions. Both neat PVDF films and hybrid ones (0.5% in wt of nanoparticles included into the polymer matrix) showed, as-deposited (un-poled), a similar β-phase content. Although the piezoelectric coefficient in the case of the hybrid films was one order of magnitude lower than that for the neat PVDF films, the robustness of the polarized areas was reported 24 h after the polarization process and after several images scanning. We thus succeeded in demonstrating that un-poled polymer thin films can show the same piezoelectric coefficient as the poled one (i.e., 10 pm/V). In addition, low electric field switching (50 MV/m) was used here compared to the typical values reported in the literature (100–150 MV/m).
Highlights
Hybrid films based on electroactive polymer with improved dielectric properties have drawn tremendous interest due to the fact of their diverse applications in the development of film based sensors and actuators [1,2,3]
We aimed to show that the optimization of the β-phase content in hybrid thin films surprisingly does not correspond to an increase in the local piezoelectric behavior of the polyvinylidene fluoride (PVDF)
Keeping in mind the needs of microelectronic applications, we focused our studies on very thin and smooth PVDF and hybrid PVDF films, containing the smallest possible percentage of inorganic nanoparticles (0.5 wt%) in order to keep the flexible characteristics of the polymer and to at the same time optimize the electroactive phase content
Summary
Hybrid films based on electroactive polymer with improved dielectric properties have drawn tremendous interest due to the fact of their diverse applications in the development of film based sensors and actuators [1,2,3]. The groups of Lanceros-Mendez and Martins have made large efforts and published a great number of works on the development and optimization of PVDF and co-polymers based on 0–3 composites using ferrite magnetic nanoparticles [18,19,20,21,22,23,24,25,26,27,28,29] The latter are the preferred candidate for ME nanocomposites, as they show high magnetostrictive coefficient λs at room temperature as well as stable magnetic properties due to the fact of their high Curie temperature [23]. The authors report that POTS’ long fluoric chains together with the small size of the nanoparticles (matching the size of PVDF–TrFE crystals) are beneficial for the polar phase crystallization of the polymer and for the robustness of the 0–3 connectivity
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