Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. The method includes forming a bottom electrode over a substrate. A dielectric layer is formed on the bottom electrode. A first top electrode layer is deposited on the dielectric layer by a first deposition process. A diffusion barrier layer is deposited on the first top electrode layer by a second deposition process different from the first deposition process. A second top electrode layer is deposited on the diffusion barrier layer by a third deposition. The third deposition process is the same as the first deposition process.

A semiconductor device including a first pad on a substrate extending in a first direction and a second direction, a lower electrode connected to and disposed on the first pad, first to third supporter layers disposed on a side wall of the lower electrode and sequentially spaced apart from each other in a third direction perpendicular to the first direction and the second direction, a dielectric film disposed on the lower electrode and the first to third supporter layers, and an upper electrode disposed on the dielectric film. At least one of a side wall of the lower electrode between the first supporter layer and the second supporter layer, and a side wall of the lower electrode between the second supporter layer and the third supporter layer includes a first portion including protrusions extending in the first direction and includes a second portion including no protrusions.

A method for fabricating a MOMCAP includes steps as follows: An Nth metal layer is formed on a substrate according to an Nth expected capacitance value of the Nth metal layer. An Nth capacitance error value between an Nth actual capacitance value of the Nth metal layer and the Nth expected capacitance value is calculated. An N+1th expected capacitance value of an N+1th metal layer is adjusted to form an N+1th actual capacitance value according to the Nth capacitance error value, and the N+1th metal layer with an N+1th actual capacitance value is formed on the Nth metal layer according to the adjusted N+1th expected capacitance value, to make the sum of the Nth actual capacitance value and the N+1th actual capacitance value equal to the sum of the Nth expected capacitance value and the N+1th expected capacitance value. N is an integer greater than 1.

A method of manufacturing a semiconductor device includes forming a preliminary lower electrode layer on a substrate, the preliminary lower electrode layer including a niobium oxide; converting at least a portion of the preliminary lower electrode layer to a first lower electrode layer comprising a niobium nitride by performing a nitridation process on the preliminary lower electrode layer; forming a dielectric layer on the first lower electrode layer; and forming an upper electrode on the dielectric layer.

A semiconductor die includes an array of first capacitor regions, each of the first capacitor regions including multiple first capacitor cell structures, wherein each first capacitor cell structure includes a plurality of first trench segments characterized by a first trench length, a first trench width, and a first trench spacing, and a first air gap width in a gap-filling material. The semiconductor die also includes a plurality of second capacitor regions interspersed in the array of first capacitor regions, each of the second capacitor region including multiple second capacitor cell structures, wherein each second capacitor cell structures includes a plurality of second trench segments characterized by a second trench length, a second trench width, a second trench spacing, and a second air gap width in the gap-filling material.

The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a MIM dual capacitor structure with an increased capacitance per unit area in a semiconductor structure. Without using additional mask layers, a second parallel plate capacitor can be formed over a first parallel plate capacitor, and both capacitors share a common capacitor plate. The two parallel plate capacitors can be connected in parallel to increase the capacitance per unit area.

A method for manufacturing a stacked capacitor structure includes: forming a first patterned structure over a substrate; forming a first bottom electrode over the first patterned structure; depositing a first dielectric film over the first bottom electrode; depositing a first top electrode layer over the first dielectric film; forming a first vertical interconnect structure; forming a second patterned structure over the first top electrode layer; forming a second bottom electrode over the second patterned structure and electrically connected to the first bottom electrode through the first vertical interconnect structure; depositing a second dielectric film over the second bottom electrode; depositing a second top electrode layer over the second dielectric film; and forming a second vertical interconnect structure extending from the first top electrode layer. The second top electrode layer is electrically connected to the first top electrode layer through the second vertical interconnect structure.

A three-dimensional metal-insulator-metal (MIM) capacitor is formed in an integrated circuit structure. The 3D MIM capacitor may include a bottom conductor including a bottom plate portion (e.g., formed in a metal interconnect layer) and vertically-extending sidewall portions extending from the bottom plate portion. An insulator layer is formed on the bottom plate portion and the vertically extending sidewall portions of the bottom conductor. A top conductor is formed over the insulating layer, such that the top conductor is capacitively coupled to both the bottom plate portion and the vertically extending sidewall portions of the bottom conductor, to thereby define an increased area of capacitive coupling between the top and bottom conductors. The vertically extending sidewall portions of the bottom conductor may be formed in a single metal layer or by components of multiple metal layers.

Various embodiments of the present disclosure are directed towards a trench capacitor with a trench pattern for yield improvement. The trench capacitor is on a substrate and comprises a plurality of capacitor segments. The capacitor segments extend into the substrate according to the trench pattern and are spaced with a pitch on an axis. The plurality of capacitor segments comprises an edge capacitor segment at an edge of the trench capacitor and a center capacitor segment at a center of the trench capacitor. The edge capacitor segment has a greater width than the center capacitor segment and/or the pitch is greater at the edge capacitor segment than at the center capacitor segment. The greater width may facilitate stress absorption and the greater pitch may increase substrate rigidity at the edge of the trench capacitor where thermal expansion stress is greatest, thereby reducing substrate bending and trench burnout for yield improvements.

A capacitor includes: a bottom electrode; a top electrode; and a hybrid dielectric layer including at least one nanosheet material disposed between the bottom electrode and the top electrode.