A method for forming a capacitor array structure includes the following steps: providing a substrate, a capacitor contact being exposed on a surface of the substrate, and the substrate including an array region and a peripheral region; forming a bottom supporting layer covering the substrate and the capacitor contact, the bottom supporting layer having a gap therein; forming a filling layer filling the gap and covering the capacitor contact and the surface of the bottom supporting layer, a thickness of the filling layer located at the peripheral region being larger than that of the filling layer located at the array region; forming supporting layers and sacrificial layers alternately stacked in a direction perpendicular to the substrate; forming a capacitor hole.

Certain aspects of the present disclosure provide a capacitor assembly, a stacked capacitor assembly, an integrated circuit (IC) assembly comprising such a stacked capacitor assembly, and methods for fabricating the same. One exemplary capacitor assembly generally includes a first array of trench capacitors and a second array of trench capacitors. The second array of trench capacitors may be disposed adjacent to and electrically coupled to the first array of trench capacitors. Additionally, the second array of trench capacitors may be inverted with respect to the first array of trench capacitors.

A semiconductor region includes an isolating region which delimits a working area of the semiconductor region. A trench is located in the working area and further extends into the isolating region. The trench is filled by an electrically conductive central portion that is insulated from the working area by an isolating enclosure. A cover region is positioned to cover at least a first part of the filled trench, wherein the first part is located in the working area. A dielectric layer is in contact with the filled trench. A metal silicide layer is located at least on the electrically conductive central portion of a second part of the filled trench, wherein the second part is not covered by the cover region.

A system and method for fabricating on-die metal-insulator-metal capacitors capable of maintaining a similar capacitance for design reuse across multiple semiconductor fabrication processes are described. In various implementations, an integrated circuit includes multiple metal-insulator-metal (MIM) capacitors. The MIM capacitors are formed between two signal nets. The integrated circuit includes multiple intermediate metal layers (or metal plates) formed between two signal nets. Subsequent semiconductor fabrication processes typically increase a number of metal plates that can be formed in the dielectric layer, such as an oxide layer, between two signal nets. To permit design reuse across multiple semiconductor fabrication processes, for a particular MIM capacitor designated to maintain a same capacitance, the additional metal plates for the particular MIM capacitor are formed as floating nets. Additionally, the same electrode plates of the particular MIM capacitor are used across the multiple semiconductor fabrication processes.

A stacked capacitor structure includes a MOS varactor and a stacked capacitor. The stacked capacitor is electrically connected to the MOS varactor. The MOS varactor includes a substrate, a gate, a first source/drain and a second source/drain. The substrate has a well, and the gate is positioned over the well. The first source/drain and the second source/drain are formed in the well and positioned at opposing sides of the gate. The stacked capacitor includes a plurality of metal layers. The metal layers are spaced from each other, stacked above the gate, and positioned below an inductive element.

A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

Integrated circuits and methods of producing the same are provided. In an exemplary embodiment, an integrated circuit includes a first capacitor with a first gate overlying a first gate dielectric that in turn overlies a first channel. a second capacitor includes a second gate overlying a second gate dielectric that in turn overlies a second channel. The second gate dielectric has a different composition than the first gate dielectric. A capacitor interconnect is in electrical communication with the first capacitor and with the second capacitor.

A metal-insulator-metal (MIM) capacitor component that includes a substrate, where the metal-insulator-metal (MIM) capacitor component is configured to form a first capacitor with a top metal and a first bottom metal having a dielectric layer therebetween; and where the metal-insulator-metal (MIM) capacitor component is configured to form a second capacitor with the top metal and a second bottom metal having the dielectric layer therebetween. Additionally, the top metal, the dielectric layer, the first bottom metal, and the second bottom metal are arranged on the substrate.

A device includes a main capacitor composed of a first plate of a first back-end-of-line (BEOL) metallization layer, a main insulator layer on the first plate, and a second plate on the main insulator layer. The second plate is composed of a second BEOL metallization layer. The device includes a first tuning capacitor of a first portion of a first BEOL interconnect trace coupled to the first plate of the main capacitor through first BEOL sideline traces. The first tuning capacitor is composed of a first insulator layer on a surface and sidewalls of the first portion of the first BEOL interconnect trace. The first tuning capacitor includes a second BEOL interconnect trace on a surface and sidewalls of the first insulator layer. The device includes a first via capture pad coupled to the second BEOL interconnect trace of the first tuning capacitor.

Embodiments are provided herein for low loss coupling capacitor structures. The embodiments include a n-type varactor (NVAR) configuration and p-type varactor (PVAR) configuration. The structure in the NVAR configuration comprises a p-doped semiconductor substrate (Psub), a deep n-doped semiconductor well (DNW) in the Psub, and a p-doped semiconductor well (P well) in the DNW. The circuit structure further comprises a source terminal of a p-doped semiconductor material within P well, and a drain terminal of the p-doped semiconductor material within the P well. Additionally, the circuit structure comprises an insulated gate on the surface of the P well, a metal pattern comprising a plurality of layers of metal lines, and a plurality of vias through the metal lines. The vias are contacts connecting the metal lines to the gate, the source terminal, and the drain terminal.