A capacitor includes: a plurality of bottom electrodes; a dielectric layer formed over the bottom electrodes; and a top electrode formed over the dielectric layer, wherein the top electrode includes a carbon-containing material and a germanium-containing material that fill a gap between the bottom electrodes.

A capacitor includes: a plurality of bottom electrodes; a dielectric layer formed over the bottom electrodes; and a top electrode formed over the dielectric layer, wherein the top electrode includes a carbon-containing material and a germanium-containing material that fill a gap between the bottom electrodes.

Improved electrodes and currents through the use of organic and organometallic high dielectric constant materials containing dispersed conductive particles in energy storage devices and associated methods are disclosed. According to an aspect, a dielectric material includes at least one layer of a substantially continuous phase material comprising a combination of organometallic having delocalized electrons, organic compositions and containing metal particles in dispersed form, in another aspect, the novel material is used with a porous electrode to further increase charge and discharge currents.

A meta-dielectric film usable in a capacitor includes composite molecules with a resistive envelope built with alkyl oligomeric single chain or branched chain oligomers having carbo-hydrogen or carbo-fluoro composition and a polarizable core molecular fragment inside the resistive envelope. The polarizable core has an electronic or ionic type of polarizability provided by electronic conductivity of the core molecular fragment or limited mobility of ionic parts of the core molecular fragment.

A meta-dielectric film usable in a capacitor includes composite molecules with a resistive envelope built with alkyl oligomeric single chain or branched chain oligomers having carbo-hydrogen or carbo-fluoro composition and a polarizable core molecular fragment inside the resistive envelope. The polarizable core has an electronic or ionic type of polarizability provided by electronic conductivity of the core molecular fragment or limited mobility of ionic parts of the core molecular fragment.

One aspect is contemplated for providing a device having a liquid crystal material exhibiting a dielectric constant of 1000 or more at a temperature at which a specific liquid crystal phase is developed, and a unit configured to apply voltage to the liquid crystal material at the temperature at which the specific liquid crystal phase is developed.

The present disclosure provides an energy storage system comprising at least one capacitive energy storage device and a DC-voltage conversion device. The capacitive energy storage device comprises at least one metacapacitor. The output voltage of the capacitive energy storage device is the input voltage of the DC-voltage conversion device. The capacitive energy storage system is capable of being charged from a power generation system and/or an electrical grid and discharging energy to a load and/or electrical grid. The capacitive energy storage system is configurable to supply external power as an operating power in a first state in which the external power is applied and/or to supply power as the operating power in a second state in which the external power is not applied.

Methods for forming a graft copolymer of a poly(vinylidene fluoride)-based polymer and at least one type of electrically conductive polymer, wherein the electrically conductive polymer is grafted on the poly(vinylidene fluoride)-based polymer are provided. The methods comprise a) irradiating a poly(vinylidene fluoride)-based polymer with a stream of electrically charged particles; b) forming a solution comprising the irradiated poly(vinylidene fluoride)-based polymer, an electrically conductive monomer and an acid in a suitable solvent; and c) adding an oxidant to the solution to form the graft copolymer. Graft copolymers of a poly(vinylidene fluoride)-based polymer and at least one type of electrically conductive polymer, wherein the electrically conductive polymer is grafted on the poly(vinylidene fluoride)-based polymer, nanocomposite materials comprising the graft copolymer, and multilayer capacitors comprising the nanocomposite material are also provided.

Methods for forming a graft copolymer of a poly(vinylidene fluoride)-based polymer and at least one type of electrically conductive polymer, wherein the electrically conductive polymer is grafted on the poly(vinylidene fluoride)-based polymer are provided. The methods comprise a) irradiating a poly(vinylidene fluoride)-based polymer with a stream of electrically charged particles; b) forming a solution comprising the irradiated poly(vinylidene fluoride)-based polymer, an electrically conductive monomer and an acid in a suitable solvent; and c) adding an oxidant to the solution to form the graft copolymer. Graft copolymers of a poly(vinylidene fluoride)-based polymer and at least one type of electrically conductive polymer, wherein the electrically conductive polymer is grafted on the poly(vinylidene fluoride)-based polymer, nanocomposite materials comprising the graft copolymer, and multilayer capacitors comprising the nanocomposite material are also provided.

Modified fluoropolymers, and methods for manufacturing modified fluoropolymers are provided. According to at least one embodiment, chemically modified fluoropolymers, via radical generation and subsequent reaction, produce fluoropolymers having fluorinated moieties and/or non-fluorinated moieties, disrupting highly coherent polar domains, wherein the non-fluorinated moieties include, for example, at least one of carbonyl, hydroxyl, alkoxy, alkyl, and/or aromatic chemical groups.