Abstract: A multilayer ceramic capacitor includes: a ceramic body including a dielectric layer, a first internal electrode and a second internal electrode arranged to face each other with the dielectric layer interposed therebetween; and a first external electrode disposed on an exterior surface of the ceramic body and a second external electrode disposed on the exterior surface of the ceramic body, wherein the ceramic body includes an active portion, forming capacity, cover portions disposed on upper and lower portions of the active portion, and margin portions disposed on a side surface of the active portion, and wherein the dielectric layer, the cover portions, and the margin portions of the active portion include magnesium (Mg) having content of more than 0 mole, and less than or equal to 1.0 mole, relative to titanium (Ti) included in the dielectric layer, the cover portions and the margin portions of the active portion.

Abstract: To provide an electrolytic capacitor with improved reliability. The electrolytic capacitor including: at least one capacitor element including an anode foil having a first part including a first end, and a second part including a second end, a dielectric layer formed on at least a surface of the second part, and a cathode part covering at least part of the dielectric layer; a package body enclosing the capacitor element; and an external electrode. At least a surface of the second part has a porous portion, and at least an end face of the first end is exposed from the package body and is in contact with the external electrode.

Abstract: A capacitor array that includes a solid electrolytic capacitor element including an anode plate made of a valve-action metal, a porous layer on at least one main surface of the anode plate, a dielectric layer on a surface of the porous layer, and a cathode layer including a solid electrolyte layer on a surface of the dielectric layer; a first anodic through-electrode electrically connected to the anode plate; a second anodic through-electrode electrically connected to the anode plate; and a first cathodic through-electrode electrically connected to the cathode layer, wherein a distance between the first cathodic through-electrode and the first anodic through-electrode is the same or substantially the same as a distance between the first cathodic through-electrode and the second anodic through-electrode in a plane view from a thickness direction of the anode plate.

Abstract: A wet capacitor is provided, and the use of an insulation fluid composition in such a capacitor. The capacitor includes a package of a metal foil and a polymeric insulating film, or of a metallized polymeric film, wherein the insulation composition includes a synthetic or natural aromatic oil and a polymer. The insulation composition is configured to undergo a thermo-reversible oil-to-gel transition at a predefined gel-point temperature. Further, methods of producing such wet capacitors are provided, optionally including additional filling materials, and methods of sealing leaks in such capacitors.

Abstract: A variable capacitor includes an enclosure having first and second conductive collars separated by an intermediate electrically insulating element. A movable capacitor plate assembly is electrically coupled to the first conductive collar, and a fixed capacitor plate assembly is electrically coupled to the second conductive collar. An actuator extends into the enclosure for advancing and retracting the movable capacitor plate assembly relative to the fixed capacitor plate assembly. A hermetically sealed volume within the enclosure contains a dielectric fluid serving as a dielectric between a capacitor plate of the movable capacitor plate assembly and a capacitor plate of the fixed capacitor plate assembly. A flexible structure is provided to contain the dielectric fluid displaced when the movable capacitor plate assembly is advanced toward the fixed capacitor plate assembly.

Abstract: Disclosed herein is a thin film capacitor that includes a capacitive insulating film having first and second surfaces opposite to each other, a first capacitive electrode covering the first surface of the capacitive insulating film, and a second capacitive electrode covering the second surface of the capacitive insulating film and including a plurality of capacitor areas divided by a slit and a plurality of fuse areas connecting two of adjacent capacitor areas. The second capacitive electrode has a structure in which a plurality of conductor films including a first conductor film and a second conductor film lower in electrical resistivity than the first conductor film are laminated.

Abstract: In an embodiment, the present disclosure pertains to a method of creating a supercapacitor. The method includes forming an anode and a cathode, each composed of a substrate having at least one of a lignin, a lignin-based composite, activated carbon, a plant extract, a cellulose by-product, biofuel waste, one or more metals, a metal oxide, a monometallic tungstate, or a bimetallic tungstate, and sandwiching an electrolyte coated separator between the anode and the cathode. In an addition embodiment, the present disclosure pertains to an electrode composed of a particle-decorated lignin. In some embodiments, the particle-decorated lignin includes particles that can include, without limitation, MnO2, NiWO4, MnO2, NiCoWO4, CoWO4, and combinations thereof. In a further embodiment, the present disclosure pertains to a supercapacitor made via the methods of the present disclosure.

Abstract: A capacitor and a method for producing a capacitor are disclosed. In an embodiment, the capacitor includes a winding having a cathode foil, an anode foil and separators arranged therebetween, an overlap-free region, wherein the cathode foil does not overlap with the anode foil in the overlap-free region, wherein the overlap-free region adjoins an overlapping region, and wherein the cathode foil overlaps with the anode foil in a lateral direction in the overlapping region, and a cathode contact arranged in the overlap-free region, the cathode contact contacting the cathode foil.

Abstract: An electronic component includes an element body including a side surface and an end surface adjacent to each other, and an external electrode disposed on the side surface and the end surface. The external electrode includes a metal layer disposed on the side surface and the end surface and made of sintered copper, a conductive resin layer that is disposed on the metal layer in such a manner that a partial region of the metal layer is exposed and contains a plurality of copper particles and a resin, and a plating layer disposed on the partial region of the metal layer and the conductive resin layer. The conductive resin includes a first portion located on the side surface. The plating layer includes a second portion located on the side surface. A thickness of the first portion is smaller than a thickness of the second portion.

Abstract: An energy storage device includes: a case including a case body and a lid; and electrode terminals (positive electrode terminal, negative electrode terminal) fixed to the lid. A junction portion for joining the case body and the lid to each other is formed on a surface of the case on an electrode terminal side. The lid includes recessed portions disposed along and adjacent to the junction portion without being disposed between the electrode terminal and the junction portion.

Abstract: A multilayer ceramic capacitor includes a multilayer body, a first internal electrode layer extending to opposing end surfaces of the multilayer body, a second internal electrode layer extending to opposing side surfaces of the multilayer body, first and second external electrodes connected to the first internal electrode layer and provided on the opposing end surfaces, and third and fourth external electrodes connected to the second internal electrode layer and provided on the opposing side surfaces. The second internal electrode layer includes a central section in a central portion of the dielectric layer and an extending section extending to the opposing side surfaces. The first internal electrode layer is larger in number than the second internal electrode layer, at least two first internal electrode layers are successively layered, and the extending section is larger in thickness than the central section located in the central portion of the dielectric layer.

Abstract: Various embodiments of an electrical component and a method of forming such component are disclosed. The electrical component includes a substrate having a first major surface, a second major surface, an alloy layer disposed on the first major surface of a substrate, and tantalum material disposed on the alloy layer such that the alloy layer is between the tantalum material and the first major surface of the substrate. The tantalum material includes bonded tantalum particles. The electrical component can also include a dielectric layer disposed on the tantalum particles, a cathode electrode disposed over the tantalum material, and an anode electrode disposed on the second major surface of the substrate.

Abstract: The present invention relates to an energy storage device comprising a flexible substrate comprising at least two patterned regions spaced apart from one another along the length of the flexible substrate. Each patterned region comprises at least one groove extending in the longitudinal direction of the substrate (web direction) having a first and a second face, wherein the first and second faces are each coated with a conductor such that there is no direct electrical communication between the conductor on the first and second faces, the at least one groove contains a material for storing electrical potential energy (e.g. capacitive material), the first and the second face of the at least one groove of each patterned region are each in electrical connection with an electrical conductor at opposing edges of the flexible substrate, and the first and the second patterned region are electrically connectable to one another.

Abstract: An electronic component includes a body including a plurality of dielectric layers, and a plurality of internal electrodes disposed with a corresponding one of the dielectric layers interposed therebetween; and an external electrode disposed on the body and connected to at least one of the plurality of internal electrodes. One of the plurality of internal electrodes includes an alloy metal including nickel, tin and aluminum. One of the plurality of internal electrodes includes a core internal electrode including a first surface and a second surface opposing each other, and a capping internal electrode disposed on the first surface of the core internal electrode and the second surface of the core internal electrode. The capping internal electrode includes a first alloy region including an alloy of nickel and aluminum.

Abstract: A capacitor and a method for producing a capacitor are disclosed. In an embodiment, a capacitor includes a winding having a cathode foil, an anode foil, separators arranged therebetween and a projection region in which the cathode foil projects beyond the anode foil, wherein, in the projection region, a plurality of layers of the cathode foil are arranged to form a bundle and are directly electrically connected to one another.

Abstract: An electronic component includes a multilayer body including a multilayer main body and side gap portions, the multilayer main body including an inner layer portion including dielectric layers and internal nickel electrode layers laminated alternately therein, and including end surfaces on both sides in a length direction. The internal nickel electrode layers are exposed at the end surfaces. External nickel layers are provided on the end surfaces. External copper electrode layers cover the end surfaces on which the external nickel layers are provided. A deviation amount in the width direction between positions of ends of two adjacent internal nickel electrode layers on both side surfaces is at least about 0.5 ?m. The external nickel layers are provided on the end surface, in a region excluding a rounded ridge portion. Nickel and tin layers are provided outside the external copper electrode layer.

Abstract: A multilayer ceramic capacitor includes a body having a dielectric layer and internal electrodes disposed to be alternately exposed to the third and fourth surfaces with the dielectric layer interposed therebetween. External electrodes include connection parts respectively formed on opposing surfaces of the body, band parts formed to extend from the connection parts to portions of side surfaces of the body, and corner parts in which the connection parts and the band parts are contiguous. A thickness of each of the external electrodes may be 50 nm to 2 ?m. The external electrodes may be formed using a barrel-type sputtering method. A ratio t2/t1 may satisfy 0.7 to 1.2, where t1 is a thickness of each connection part and t2 is a thickness of each band part. A ratio t3/t1 may satisfy 0.7 to 1.0, where t3 is a thickness of each corner part.

Abstract: A stacked solid electrolytic capacitor is provided in the present disclosure. The stacked solid electrolytic capacitor includes a capacitive module, a conductive module and a packaging structure. The capacitive module includes capacitive units stacked up sequentially. The conductive module includes a positive terminal, a negative terminal and at least one anti-oxidizing layer. The positive terminal is electrically connected to one of the capacitive units. The negative terminal is electrically connected to the one of the capacitive units through a conductive paste layer. The at least one anti-oxidizing layer is arranged between the negative terminal and the conductive paste layer. The packaging structure surrounds the capacitive module and the conductive module. Therefore, it is difficult for an oxide layer forming between the negative terminal and the capacitive units, and the equivalent series resistance of the stacked solid electrolytic capacitor can be reduced.

Abstract: A multilayer ceramic electronic component includes a ceramic body including a dielectric layer and first and second internal electrodes with the dielectric layer interposed therebetween, the dielectric layer and the first and second internal electrodes arranged to be stacked, and a first cover portion disposed on the capacitance portion, and a second cover portion disposed on the capacitance portion, a first external electrode connected to the first internal electrode, and a second external electrode connected to the second internal electrode. The first cover portion and the second cover portion include a cover reinforcing layer including graphene.

Abstract: A nanowire energy storage device such as a nanowire battery or a capacitor having a cathode comprising a plurality of nanowires and an anode comprising a plurality of nanowires interlaced with the plurality of nanowires of the cathode, and embedded in a PMMA gel electrolyte.