The
fabrication of a core–shell structure is an effective
method of obtaining a composite film with a high energy density. Herein,
we prepared a new type of composite film with high energy density
and energy efficiency by using silica-coated core–shells on
poly(vinylidene fluoride) (PVDF) particles that comprised a high proportion
of polar phases rather than inorganics with high dielectric constants.
We prepared PVDF particles with a high proportion of the β-phase
using emulsion polymerization. Subsequently, we prepared PVDF@SiO2 core–shell particles by coating silica using the sol–gel
method. The resultant PVDF@SiO2–PVDF exhibited a
low reduction in the dielectric constant because of the lower amount
of silica than that in other dense silica particles, which was verified
through dielectric constant measurements and theoretical calculations.
In addition, when the PVDF@SiO2 particle contained 40 wt
% silica, a high breakdown strength of 598.95 MV/m was confirmed.
Therefore, we verified that the PVDF@SiO2–PVDF composite
film has a high discharge energy density of 12.051 J/cm3 when the PVDF@SiO2 is 40 wt %. In addition, the domain
size is limited by the silica shell, resulting in a high energy efficiency
of 88.22%, which indicated a potential for the utilization of the
composite film in energy storage devices. These results offer a novel
strategy for the development of polymer-based capacitors with high
energy densities and efficiencies.
This Letter reports a novel approach to the fabrication of a biomimicking surface by modification of an end-functionalizable smooth polymer cushion constructed via chemoselective ligation with a phospholipid-like molecule containing oxyamine groups. The mobility of a phospholipid bilayer formed by vesicle fusion on the phospholipid-like molecule terminated polymer film was characterized by fluorescence recovery after bleaching. Platelet adhesion, as one measure of biocompatibility of the film was also studied and compared to other surfaces such as polyethylene or poly(dimethylsiloxane). The results show that the end-functionalized smooth polymer cushion has potential as a biocompatible platform to reconstitute membrane proteins.
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