A capacitor component includes a porous body, a first electrode layer covering surfaces of pores of the porous body, a dielectric layer covering the first electrode layer, and a second electrode layer filling the pores of the porous body and covering the dielectric layer.

Horizontal-trench on-chip capacitors are provided. In one aspect, a method of forming a capacitor includes: forming alternating sacrificial/active nanosheets on a wafer; patterning the nanosheets into a fin stack(s); burying the fin stack(s) in an ILD; removing the ILD from a first side of the fin stack(s), forming a first cavity; filling the first cavity with a semiconductor material that interconnects the nanosheets of the active material; implanting ions into the nanosheets, semiconductor material and wafer; removing the ILD from a second side of the fin stack(s) forming a second cavity; selectively removing the nanosheets of the sacrificial material, creating gaps between the nanosheets of the active material; depositing a dielectric into/lining the gaps and second cavity; and filling the gaps and second cavity with a conductor. A capacitor is also provided.

The present invention discloses a method of manufacturing a capacitor, which includes the steps of forming a capacitor recess in a sacrificial layer, wherein the sidewall of capacitor recess has a wave profile, forming a bottom electrode layer on the sidewall of capacitor recess, filling up the capacitor recess with a supporting layer, removing the sacrificial layer to forma capacitor pillar made up by the bottom electrode layer and the supporting layer, forming a capacitor dielectric layer on the capacitor pillar, and forming a top electrode layer on the capacitor dielectric layer.

A semiconductor substrate has a front face with a first dielectric region. A capacitive element includes, on a surface of the first dielectric region at the front face, a stack of layers which include a first conductive region, a second conductive region and a third conductive region. The second conductive region is electrically insulated from the first conductive region by a second dielectric region. The second conductive region is further electrically insulated from the third conductive region by a third dielectric region. The first and third conductive regions form one plate of the capacitive element, and the second conductive region forms another plate of the capacitive element.

A capacitive element is located in an active region of the substrate and on a front face of the substrate. The capacitive element includes a first electrode and a second electrode. The first electrode is formed by a first conductive region and the active region. The second electrode is formed by a second conductive region and a monolithic conductive region having one part covering a surface of said front face and at least one part extending into the active region perpendicularly to said front face. The first conductive region is located between and is insulated from the monolithic conductive region and a second conductive region.

An integrated circuit device includes a conductive region on a substrate and a lower electrode structure including a main electrode part spaced apart from the conductive region and a bridge electrode part between the main electrode part and the conductive region. A dielectric layer contacts an outer sidewall of the main electrode part. To manufacture the integrated circuit device, a preliminary bridge electrode layer is formed in a hole of a mold pattern on the substrate, and the main electrode part is formed on the preliminary bridge electrode layer in the hole. The mold pattern is removed to expose a sidewall of the preliminary bridge electrode layer, and a portion of the preliminary electrode part is removed to form the bridge electrode part. The dielectric layer is formed to contact the outer sidewall of the main electrode part.

An apparatus and associated method for an energy-storage device (e.g., a capacitor) having a plurality of electrically conducting electrodes including a first electrode and a second electrode separated by a non-electrically conducting region, and wherein the non-electrically conducting region further includes a non-uniform permittivity (K) value. In some embodiments, the method includes providing a substrate; fabricating a first electrode on the substrate; and fabricating a second electrode such that the second electrode is separated from the first electrode by a non-electrically conducting region, wherein the non-electrically conducting region has a non-uniform permittivity (K) value. The capacitor devices will find benefit for use in electric vehicles, of all kinds, uninterruptible power supplies, wind turbines, mobile phones, and the like requiring wide temperature ranges from several hundreds of degrees C. down to absolute zero, consumer electronics operating in a temperature range of 55 degrees C. to 125 degrees C.

A method for fabricating a semiconductor device is provided. The method includes the actions of: providing a substrate comprising a preliminary pattern formed thereon; forming an opening through the preliminary pattern to expose a conductive portion in the substrate; forming a dielectric layer on a sidewall of the opening; performing a dry etching process to form a hole in the conductive portion; removing the dielectric layer; and depositing a conductive pattern over the sidewall of the opening and in the hole.

A method for fabricating a semiconductor device is provided. The method includes the actions of: providing a substrate comprising a preliminary pattern formed thereon; forming an opening through the preliminary pattern to expose a conductive portion in the substrate; forming a spacer on a sidewall of the opening; performing an wet etching process to form a hole in the conductive portion; removing the spacer; and depositing a conductive pattern over the sidewall of the opening and a surface of the hole.

Device and methods are provided for fabricating semiconductor devices in which metal-insulator-metal (MIM) capacitor devices are integrally formed with vertical field effect transistor (FET) devices. For example, a semiconductor device includes first and second vertical FET devices, and a capacitor device, formed in different device regions of a substrate. A gate electrode of the first FET device and a first capacitor electrode of the capacitor device are patterned from a same first layer of conductive material. A gate electrode of the second FET device and a second capacitor electrode of the capacitor device are patterned from a same second layer of conductive material. A gate dielectric layer of the second FET device and a capacitor insulator layer of the capacitor device are formed from a same layer of dielectric material.