The present invention provides an electrode material for an electrochemical capacitor having high surface utilization efficiency, composed of a porous carbon material capable of further contributing to higher electrostatic capacitance of the electrochemical capacitor and to development of high rate characteristics; the porous carbon material having a co-continuous structural portion in which a carbon skeleton and voids form respective continuous structures, the co-continuous structural portion having a structural period of 0.002 m to 20 m.

The method of making a supercapacitor using porous activated carbon from cow dung includes converting cow dung to porous activated carbon by, in a first step, preparing the dung waste by washing and drying the dung waste, and heating the dung waste in a vacuum environment to form pre-carbonized carbon. In a second step, the pre-carbonized carbon is impregnated with phosphoric acid to form a slurry, which is dried, ground, and heated in a vacuum to between 600-900 C. to form porous activated carbon. The porous activated carbon is mixed with a binder, acetylene black, and an organic solvent to form a paste, which is dried on a conductive metal foil to form an electrode. Two such electrodes (an anode and cathode) are coated with an electrolyte gel (e.g., aqueous potassium hydroxide) and separated by a polymer (e.g., PTFE) membrane to form the supercapacitor.

Methods of forming microelectronic structures are described. Embodiments of those methods may include forming an electrochemical capacitor device by forming pores in low-purity silicon materials. Various embodiments described herein enable the fabrication of high capacitive devices using low cost techniques.

Methods of forming microelectronic structures are described. Embodiments of those methods may include forming an electrochemical capacitor device by forming pores in low-purity silicon materials. Various embodiments described herein enable the fabrication of high capacitive devices using low cost techniques.

In an illustrative embodiment, a supercapacitor system includes a common bus and a number of supercapacitor units, each of the supercapacitor units including one or more supercapacitors, coupled to the common bus via a balancing circuit, where each balancing circuit is configured to balance a charge of the one or more supercapacitors in the supercapacitor units by conducting current to supercapacitor units with a lower charge from supercapacitor units with a higher charge over the common bus, each balancing circuit including at least a first switch and a second switch, each switch controlled by a clock signal.

A device for depassivation of an energy storage device having an anode, a cathode and a core with an electrolyte, the device including: a first switch configured to provide a positive input voltage to the anode; a second switch configured to provide a negative input voltage to the anode; and a controller configured to: detect that a first predetermined event related to a buildup of passivation has occurred with regard to the energy storage device; switch between a positive input voltage and a negative input voltage provided to the anode at a frequency sufficient to depassivate the anode; discontinue the switching when a second predetermined event related to passivation has occurred.

A device for depassivation of an energy storage device having an anode, a cathode and a core with an electrolyte, the device including: a first switch configured to provide a positive input voltage to the anode; a second switch configured to provide a negative input voltage to the anode; and a controller configured to: detect that a first predetermined event related to a buildup of passivation has occurred with regard to the energy storage device; switch between a positive input voltage and a negative input voltage provided to the anode at a frequency sufficient to depassivate the anode; discontinue the switching when a second predetermined event related to passivation has occurred.

A package electric double-layer capacitor having a first terminal that extends from a package at a first corner of a first cell, which is adjacent to a second cell, on one side in a second direction orthogonal to a first direction. A second terminal extends from the package at the first corner in the first direction and on a side of the first terminal opposite to the second cell. A third terminal extends from the package at a second corner of the second cell, which is adjacent to the first cell and the first corner. A fourth terminal extends from the package at the second corner in the first direction and on a side of the third terminal opposite to the first cell.

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.

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.