A method of manufacturing a semiconductor structure includes: forming a first oxide layer over a landing pad layer; forming a middle patterned dielectric layer over the first oxide layer; sequentially forming a second oxide layer and a top dielectric layer over the middle patterned dielectric layer; forming a trench through the top dielectric layer, the second oxide layer and the first oxide layer; conformally forming a bottom conductive layer in the trench; removing a portion of the top dielectric layer adjacent to the trench to expose a portion of the second oxide layer beneath the portion of the top dielectric layer; and performing an etching process to remove the second oxide layer and the first oxide layer. A semiconductor structure is also provided.

The disclosed technology relates to a metal-insulator-metal capacitor (MIMCAP) integrated as part of a back-end-of-line of an integrated circuit (IC). In one aspect, a MIMCAP comprises a first planar electrode having perforations formed therethrough, and a metal-insulator-metal (MIM) stack lining inner surfaces of cavities formed in the perforations and extending into the substrate. The MIMCAP additionally comprises a second electrode having a planar portion and metal extensions extending from the planar portion into the cavities. The first electrode and the planar portion of the second electrode are formed of or comprise planar metal areas of the respective metallization levels, which can be formed by a damascene process, which allows for a reduction of the series resistance. A low aspect ratio can be obtained using one electrode having a 3D-structure (the electrode having extensions extending into the cavities).

Various embodiments of transistor assemblies, integrated circuit devices, and related methods are disclosed herein. In some embodiments, a transistor assembly may include a base layer in which a transistor is disposed, a first metal layer, and a second metal layer disposed between the base layer and the first metal layer. The transistor assembly may also include a capacitor, including a sheet of conductive material with a channel therein, disposed in the base layer or the second metal layer and coupled to a supply line of the transistor. Other embodiments may be disclosed and/or claimed.

A concentric capacitor structure generally comprising concentric capacitors is disclosed. Each concentric capacitor comprises a first plurality of perimeter plates formed on a first layer of a substrate and a second plurality of perimeter plates formed on a second layer of the substrate. The first plurality of perimeter plates extend in a first direction and the second plurality of perimeter plates extend in a second direction different than the first direction. A first set of the first plurality of perimeter plates is electrically coupled to a first set of the second plurality of perimeter plates and a second set of the first plurality of perimeter plates is electrically coupled to a second set of the second plurality of perimeter plates. A plurality of capacitive cross-plates are formed in the first layer such that each cross-plate overlaps least two of the second plurality of perimeter plates.

Back end of the line (BEOL) capacitors and methods of manufacture are provided. The method includes forming wiring lines on a substrate, with spacing between adjacent wiring lines. The method further includes forming an air gap within spacing between the adjacent wiring lines by deposition of a capping material. The method further includes opening the air gap between selected adjacent wiring lines. The method further includes depositing conductive material within the opened air gap.

A method is provided for forming a metal-insulator-metal capacitor in a replacement metal gate module. The method includes providing a gate cap formed on a gate. The method further includes removing a portion of the gate cap and forming a recess in the gate. A remaining portion of the gate forms a first electrode of the capacitor. The method also includes depositing a dielectric on remaining portions of the gate cap and the remaining portion of the gate. The method additionally includes depositing a conductive material on the dielectric. The method further includes removing a portion of the conductive material and portions of the dielectric to expose a remaining portion of the conductive material and a remaining portion of the dielectric. The remaining portion of the conductive material forms a second electrode of the capacitor. The remaining portion of the dielectric forms an insulator of the capacitor.

Semiconductor devices are provided. Each of the semiconductor devices may include a plurality of electrodes. Moreover, each of the semiconductor devices may include a supporting pattern connected to sidewalls of the plurality of electrodes. Related methods of forming semiconductor devices are also provided. For example, the methods may include forming the supporting pattern before forming the plurality of electrodes.

A metal-insulator-metal capacitor is provided in a replacement metal gate module having a gate cap formed on a gate. The capacitor includes a first electrode formed within a portion of the gate using a metal forming the gate. The first electrode has a horizontal component and a stack rising from at least a portion of the horizontal component. The capacitor further includes an insulator formed within a recess. The recess is formed to have a lower portion and walls rising from edges of the lower portion. The lower portion is formed on a different portion of the horizontal component than the stack. The walls are formed adjacent to a side wall of the stack and a portion of the gate cap. The capacitor also includes a second electrode formed within the recess and on the insulator.

A capacitor includes a bottom electrode and a top electrode positioned above the bottom electrode. The top electrode and the bottom electrode are conductively coupled to one another. A middle electrode is positioned between the bottom electrode and the top electrode. A lower dielectric layer is positioned between the bottom electrode and the middle electrode. An upper dielectric layer positioned between the middle electrode and the top electrode. A first contact is conductively coupled to the top electrode. A second contact is conductively coupled to the middle electrode.

A high-k dielectric metal trench capacitor and improved isolation and methods of manufacturing the same is provided. The method includes forming at least one deep trench in a substrate, and filling the deep trench with sacrificial fill material and a poly material. The method further includes continuing with CMOS processes, comprising forming at least one transistor and back end of line (BEOL) layer. The method further includes removing the sacrificial fill material from the deep trenches to expose sidewalls, and forming a capacitor plate on the exposed sidewalls of the deep trench. The method further includes lining the capacitor plate with a high-k dielectric material and filling remaining portions of the deep trench with a metal material, over the high-k dielectric material. The method further includes providing a passivation layer on the deep trench filled with the metal material and the high-k dielectric material.