A capacitor element includes an anode body including a porous region located at a surface of the anode body, a dielectric layer that covers at least a part of the anode body, and a cathode layer that covers at least a part of the dielectric layer. The anode body includes an anode part and a cathode formation part on which the cathode layer is disposed, the cathode formation part being adjacent to the anode part. At least a part of the porous region of the anode part includes a thin-thickness region that is thinner than the porous region in the cathode formation part, and a metal substrate is stacked on at least a part of the thin-thickness region. The metal substrate is denser than the porous region in the cathode formation part.

A tantalum capacitor including a capacitor body including a tantalum body including a tantalum wire exposed on one side and a capsule portion configured to surround the tantalum body so that an end of the tantalum wire is exposed; a first metal layer on one side of the capacitor body and a second metal layer on one side of the first metal layer; and an external electrode connected to the first metal layer, wherein the first metal layer includes Cr (chromium), Ti (titanium), an alloy thereof, or a mixture thereof, and the second metal layer includes Ni (nickel), an alloy including the same, or a mixture including the same.

An energy-storage device is formed from a first and a second yarn, each yarn including a plurality of nanowires including aluminum and/or a transition metal. An anode pad is in contact with the first yarn and a cathode pad is in contact with the second yarn. Alternatively, first and second metallic electrodes may be disposed substantially in parallel, with pluralities of nanowires including aluminum and/or a transition metal extending therefrom. In another embodiment, a supercapacitor may include a niobium yarn including a plurality of niobium nanowires. Each niobium nanowire may include at least (i) a first section comprising at least one of unoxidized niobium and niobium oxide; (ii) a second section comprises a niobium pentoxide layer; and (iii) a third section comprises a layer formed by dipping the niobium nanowire in at least one of a conductive polymer and a liquid metal.

Disclosed is an electrode leading-out method and packaging method for a tantalum electrolytic capacitor. The electrode leading-out method includes the following steps: S1, fabricating an insulating protective layer outside an electrode body of the tantalum electrolytic capacitor; S2, exposing a cathode leading-out part on a cathode pre-leading-out part, and exposing a tantalum core leading-out end in an area where a terminal of a tantalum core is located; S3, depositing a metal layer on each of the cathode leading-out part and the tantalum core leading-out end which are exposed; and S4, fabricating an outer electrode for mounting on each of the metal layer of the cathode leading-out part and the metal layer of the tantalum core leading-out end so as to respectively lead out a cathode and an anode.

Provided is a solid electrolytic capacitor having a lower leakage current than a conventional solid electrolytic capacitor. The solid electrolytic capacitor includes: an anode foil having a surface on which an oxide film is formed; a cathode foil; and a separator disposed between the anode foil and the cathode foil, wherein a solid electrolyte made of a conductive high-molecular weight compound in a fine particle form and a water-soluble high-molecular weight compound solution which is formed of a water-soluble high-molecular weight compound in a liquid form, water and alcohol having a nitro group are introduced into a gap formed between the anode foil and the cathode foil in a state where the water-soluble high-molecular weight compound solution surrounds the solid electrolyte.

A wet electrolytic capacitor that contains a casing that contains a cylindrical sidewall is provided. The cylindrical sidewall defines an inner surface that surrounds an interior. First and second outer anodes are positioned within the interior of the casing. The first outer anode has a radiused sidewall and an opposing planar sidewall and the second outer anode has a radiused sidewall and an opposing planar sidewall. A central anode is also positioned within the interior of the casing between the first and second outer anodes. The central anode contains opposing first and second outer sidewalls intersecting with opposing first and second inner sidewalls. The first and second inner sidewalls are planar, and the first planar inner sidewall of the central anode faces the planar sidewall of the first outer anode and the second planar inner sidewall of the central anode faces the planar sidewall of the second outer anode.

A wet electrolytic capacitor that contains a casing that contains a sidewall extending to an upper end to define an opening is provided. The sidewall further defines an inner surface that surrounds an interior. At least one anode and at least one cathode are positioned within the interior of the casing, wherein the cathode contains an electrochemically-active material and further wherein an anode lead extends from the anode. A working electrolyte is in electrical contact with the anode and the electrochemically-active material. The capacitor also comprises a lid assembly that contains a lid positioned on an upper end of the casing sidewall, wherein the lid defines an orifice through which a tube extends. The tube accommodates the anode lead that extends from the anode. A dielectric layer is formed on a surface of the tube.

An energy-storage device is formed from a first and a second yarn, each yarn including a plurality of nanowires including aluminum and/or a transition metal. An anode pad is in contact with the first yarn and a cathode pad is in contact with the second yarn. Alternatively, first and second metallic electrodes may be disposed substantially in parallel, with pluralities of nanowires including aluminum and/or a transition metal extending therefrom. In another embodiment, a supercapacitor may include a niobium yarn including a plurality of niobium nanowires. Each niobium nanowire may include at least (i) a first section comprising at least one of unoxidized niobium and niobium oxide; (ii) a second section comprises a niobium pentoxide layer; and (iii) a third section comprises a layer formed by coating the niobium nanowire in at least one of a conductive polymer and a liquid metal.

A tantalum capacitor includes a tantalum body having one surface which a tantalum wire extends from, a molded portion including first and second surfaces facing each other in a first direction and third and fourth surfaces facing each other in a second direction, and surrounding the tantalum body, a first lead frame including a first electrode portion in contact with the second surface of the molded portion, a second electrode portion connected to the first electrode portion, a third electrode portion connected to the second electrode portion, and a fourth electrode portion connected to the third electrode portion and the tantalum wire, and a second lead frame disposed to be in contact with the second surface of the molded portion and spaced apart from the first lead frame. The second electrode portion and the third electrode portion are inclined in different directions with respect to the second surface.

Provided herein is a method for forming a capacitor and an improved capacitor formed by the method. The method comprises providing an anode with an anode lead extending therefrom. A dielectric is formed on the anode thereby forming an anodized anode. A cathode layer is formed over the dielectric wherein the cathode layer is formed by applying a conductive polymer solution or dispersion and applying a primer solution or dispersion comprising a monophosphonium or monosulfonium cation.