An energy storage system includes, in an exemplary embodiment, a first current collector having a first surface and a second surface, a first electrode including a plurality of carbon nanotubes on the second surface of the first current collector. The plurality of carbon nanotubes include a polydisulfide applied onto a surface of the plurality of nanotubes. The energy storage system also includes an ionically conductive separator having a first surface and a second surface, with first surface of the ionically conductive separator positioned on the first electrode, a second current collector having a first surface and a second surface, and a second electrode including a plurality of carbon nanotubes positioned between the first surface of the second current collector and the second surface of the ionically conductive separator.

A laminated ceramic capacitor that includes a ceramic laminated body having a stacked plurality of ceramic dielectric layers and a plurality of internal electrodes opposed to each other with the ceramic dielectric layers interposed therebetween, and external electrodes on the outer surface of the ceramic laminated body and electrically connected to the internal electrodes. The internal electrodes contain Ni and Sn, a proportion of the Sn/(Ni+Sn) ratio is 0.001 or more in molar ratio is 75% or more in a region of the internal electrode at a depth of 20 nm from a surface opposed to the ceramic dielectric layer, and the proportion of the Sn/(Ni+Sn) ratio is 0.001 or more in molar ratio is less than 40% in a central region in a thickness direction of the internal electrode.

A laminated ceramic capacitor that includes a ceramic laminated body having a stacked plurality of ceramic dielectric layers and a plurality of internal electrodes opposed to each other with the ceramic dielectric layers interposed therebetween, and external electrodes on the outer surface of the ceramic laminated body and electrically connected to the internal electrodes. The internal electrodes contain Ni and Sn, a proportion of the Sn/(Ni+Sn) ratio is 0.001 or more in molar ratio is 75% or more in a region of the internal electrode at a depth of 20 nm from a surface opposed to the ceramic dielectric layer, and the proportion of the Sn/(Ni+Sn) ratio is 0.001 or more in molar ratio is less than 40% in a central region in a thickness direction of the internal electrode.

The present disclosure discloses the laminated ceramic chimp component including an element part having a ceramic main body and an internal electrode placed in the ceramic main body; an external electrode part having a first external electrode and a second external electrode, the first and second external electrodes being provided with side electrodes covering both side surfaces of the ceramic main body, respectively, upper electrodes covering portions of both sides of an upper surface of the ceramic main body, respectively, and lower electrodes covering portions of both sides of a lower surface of the ceramic main body, respectively; and a nano thin film layer formed of electric insulation material and applied to a region including the upper electrodes, the method for manufacturing the same and the atomic layer deposition apparatus for the same.

An electronic component includes a ceramic element, glass-containing Au layers formed on both surfaces of the ceramic element, and an Au—Sn alloy layer formed on at least one of the glass-containing Au layers; the electronic component further includes a pure-Au layer between the glass-containing Au layer and the Au—Sn alloy layer; furthermore, the Au—Sn alloy layer has an Au—Sn eutectic structure.

A method for manufacturing a capacitor includes a step of forming a case integrated with a terminal unit designed to be connected with an external terminal, and a step of housing a capacitor element in the case so that the terminal unit is electrically connected to the capacitor element. The step of forming the case includes heating a metal mold to a temperature less than or equal to a glass transition temperature of a thermoplastic resin that is a material for the case. The metal mold internally has a mold part that is a hollow part having a shape of the case. And the step of forming the case further includes, after the heating of the metal mold and inserting the terminal unit into the mold part, injecting the thermoplastic resin in a molten state into the mold part of the metal mold.

An electrode manufacturing apparatus manufactures a strip-shaped doped electrode by doping an active material contained in a layer of a strip-shaped electrode precursor with alkali metal. The electrode manufacturing apparatus includes a sensor configured to detect a mark that the electrode precursor has, at least one doping tank that stores a solution that contains alkali metal ions, a conveyer member configured to convey the electrode precursor along a path passing through the doping tank, a counter electrode member that is accommodated in the doping tank, a connector configured to electrically connect the electrode precursor and the counter electrode member, a power source configured to flow an electric current to the counter electrode member via the connector, and a power controller configured to control the power source based on a result of detection by the sensor.

An electronic component includes an electronic component main body including a body and an external electrode disposed on the body. The body includes a dielectric layer and an internal electrode. The electronic component further includes a coating portion including a coating layer, disposed on an external surface of the electronic component main body, and a plurality of projections disposed on the coating layer.

The invention relates to a capacitive block for electrical equipment, including a housing, at least one capacitive element (5) having a first end housed in said housing and a second end (9), which is opposite to the first end (7) and which extends out of said housing, an end-stop (11), said end-stop (11) being fixed to the second end (9) of the capacitive element (5), at least one spacer (13), which butts against said end-stop (11), so as to determine the distance between the second end (9) of the capacitive element (5) and a bottom of said housing.

An electronic component includes a microbody including a body including a plurality of dielectric layers and a plurality of internal electrodes disposed with a corresponding dielectric layer interposed therebetween, and an electrode layer disposed on an external side surface of the body and connected to a portion of the plurality of internal electrodes; and a sealing thin film. The microbody includes a microhole extending in at least a portion of the dielectric layer, the internal electrode, and the electrode layer through a surface of the microbody. The sealing thin film includes an internal sealing thin film disposed in at least a portion of an internal space of the open microhole to seal the microhole.