Aspects generally relate to a capacitor formed by a first conductive plate and a second conductive plate with an insulating material located between the first and second conductive plates. A third conductive plate is coupled to the second conductive plate, and a size or an overlap of the third conductive layer to the insulating layer and first conductive plate are adjusted to achieve a desired overall capacitance value of the capacitor.

A capacitor includes a first plate and a second plate parallel to the first plate. An RF source includes a first line and a second line through which RF is fed. The first line is electrically connected to the first plate. The second line is passed through the first and second plates and then looped around the first and second plates, and the pass and loop of the second line is repeated at least once. The second line is then passed through the first plate and electrically connected to the second plate to form a capacitor having negative capacitance.

An electrode element (1) for an energy storage unit (200), such as a capacitor, has an electrode body (100) made of an active electrode material (E), wherein the electrode body (100) includes one or more of: at least one cavity (110) on its surface or in its interior; at least one partial volume (120) of lower density; and/or a surface coating (D) covering at least a portion of the surface of the electrode body (100), such that the surface area covered by the surface coating (D) remains unwetted when in contact with an electrolyte. Energy storage units (200) incorporating the electrode element (1) are particularly suitable for use in implantable electrotherapeutic devices.

A multilayer ceramic electronic component includes an element body. The element body includes a capacitance region and an exterior region. The capacitance region is formed by alternately laminating inner dielectric layers and internal electrode layers having different polarities. The exterior region is laminated outside the capacitance region in a laminating direction and formed by outer dielectric layers. The internal electrode layers contain a main component of copper and/or silver. An exterior void ratio is larger than a capacitance void ratio, in which the exterior void ratio is an area ratio of voids contained in the exterior region, and the capacitance void ratio is an area ratio of voids contained in the capacitance region.

A multilayer ceramic electronic component includes an element body. The element body includes a capacitance region and an exterior region. The capacitance region is formed by alternately laminating inner dielectric layers and internal electrode layers having different polarities. The exterior region is laminated outside the capacitance region in a laminating direction and formed by outer dielectric layers. The internal electrode layers contain a main component of copper and/or silver. An exterior void ratio is larger than a capacitance void ratio, in which the exterior void ratio is an area ratio of voids contained in the exterior region, and the capacitance void ratio is an area ratio of voids contained in the capacitance region.

A multilayer ceramic electronic component includes an element body in which dielectric layers and internal electrode layers having different polarities are laminated alternately. The dielectric layers contain a main component of a perovskite-type compound represented by (Ba.sub.1-a-bSr.sub.aCa.sub.b).sub.m(Ti.sub.1-c-dZr.sub.cHf.sub.d)O.sub.3. 0.94<m<1.1, 0a1, 0b1, 0c1, and 0d1 are satisfied. The dielectric layers contain a first sub-component of 50 mol or more to the main component of 100 mol. The first sub-component contains a boron oxide and/or a lithium oxide. The internal electrode layers contain a main component of copper and/or silver.

A multilayer ceramic electronic component includes an element body in which dielectric layers and internal electrode layers having different polarities are laminated alternately. The dielectric layers contain a main component of a perovskite-type compound represented by (Ba.sub.1-a-bSr.sub.aCa.sub.b).sub.m(Ti.sub.1-c-dZr.sub.cHf.sub.d)O.sub.3. 0.94<m<1.1, 0a1, 0b1, 0c1, and 0d1 are satisfied. The dielectric layers contain a first sub-component of 50 mol or more to the main component of 100 mol. The first sub-component contains a boron oxide and/or a lithium oxide. The internal electrode layers contain a main component of copper and/or silver.

The present invention is directed to a multilayer ceramic capacitor comprising a first external terminal disposed along a first end, a second external terminal disposed along a second end that is opposite the first end, and an active electrode region containing alternating dielectric layers and active electrode layers. At least one of the electrode layers comprises a first electrode and a second electrode. The first electrode is electrically connected with the first external terminal and has a first electrode arm comprising a main portion and a step portion. The main portion has a lateral edge extending from the first end of the multilayer capacitor and the step portion has a lateral edge offset from the lateral edge of the main portion. The second electrode is electrically connected with the second external terminal.

A parallel plate capacitor including a cathode core that further includes a pair of parallel electrodes and a dielectric material layer positioned between the pair of parallel electrodes. The capacitor also includes a dielectric liquid medium, where the cathode core is at least partially submerged in the dielectric liquid medium.

A capacitor comprises an electrically conductive cylinder, an electrically conductive or semi-conductive cylindrical shell or shell segment arranged concentrically around the electrically conductive cylinder, and a dielectric arranged between the electrically conductive cylinder and the electrically conductive or semi-conductive cylindrical shell or shell segment. The dielectric comprises at least one dielectric layer having a positive thermal coefficient of relative permittivity, and at least one compensation dielectric layer having a negative thermal coefficient of relative permittivity. The thermal coefficient of relative permittivity is thereby selected such that the capacitance value of the capacitor is constant within a stability margin over a predefined temperature interval.