Structures of a semiconductor device structure are provided. The semiconductor device structure includes a first insulating layer formed over a semiconductor substrate and an interconnect structure formed in the first insulating layer. The semiconductor device structure also includes a second insulating layer formed over the first insulating layer and a capacitor device embedded in the second insulating layer. The capacitor device includes a first capacitor electrode layer electrically connected to the interconnect structure, a capacitor insulating stack formed over the first capacitor electrode layer and a second capacitor electrode layer formed over the capacitor insulating stack. The capacitor insulating stack includes first layers alternatingly stacked with second layers.

Integrated capacitor structures are described. In an example, an interconnect structure includes a first layer of conductive material and a second layer of conductive material. The first layer includes a first horizontal portion having a first opening and extending along a first horizontal plane, and a first vertical portion. The second layer includes a second horizontal portion having a second opening and extending along a second horizontal plane, and a second vertical portion. The interconnect structure also includes a dielectric extending along a third horizontal plane between the first and second horizontal portions, and having one or more openings. The first vertical component extends upward from the first horizontal portion, through one opening in the dielectric and the second opening of second layer, and the second vertical component extends downward from the second horizontal portion, through another opening in the dielectric and the first opening of first layer.

Apparatuses, memory systems, capacitor structures, and techniques related to ferroelectric capacitors having a hafnium-zirconium oxide film between the electrodes of the capacitor are discussed. The hafnium-zirconium oxide film is thin and has large crystallite grains. The thin large grain hafnium-zirconium oxide film having large grains is formed by depositing a thick hafnium-zirconium oxide film and annealing the thick hafnium-zirconium oxide film to establish the large grain size, and etching back the hafnium-zirconium oxide film to the desired thickness for deployment in the ferroelectric capacitor.

A capacitor includes a first electrode, a second electrode spaced apart from the first electrode, a dielectric layer arranged between the first electrode and the second electrode, and an interface layer arranged between the second electrode and the dielectric layer, wherein the interface layer includes a first element, a second element, and a third element, the first element includes aluminum (Al), the second element includes gallium (Ga), and the third element includes oxygen (O).

Described is a ferroelectric-based capacitor that improves reliability of a ferroelectric memory by using low-leakage insulating thin film. In one example, the low-leakage insulating thin film is positioned between a bottom electrode and a ferroelectric oxide. In another example, the low-leakage insulating thin film is positioned between a top electrode and ferroelectric oxide. In yet another example, the low-leakage insulating thin film is positioned in the middle of ferroelectric oxide to reduce the leakage current and improve reliability of the ferroelectric oxide.

A semiconductor device includes a drain, a substrate, an epitaxial layer, and a semiconductor layer. The semiconductor layer includes a source region located on a side the semiconductor layer away from the epitaxial layer. A trench extending to the epitaxial layer is disposed on a side of the source region is away from the epitaxial layer. A gate, an electrode plate, a first shield gate, and a second shield gate are disposed in the trench. The electrode plate is located between the first shield gate and the second shield gate. The trench is further filled with an oxidized layer structure. The first shield gate and the second shield gate are separately spaced from the electrode plate to form electrode plate capacitance. One of the source region, the drain, and the gate is electrically connected to the electrode plate a first electrode, and a second one of the source region, the drain, and the gate is electrically connected to the shield gate structure.

The present disclosure is directed to a method for forming metal insulator metal decoupling capacitors with scalable capacitance. The method can include forming a first redistribution layer with metal lines on a portion of a polymer layer, depositing a photoresist layer on the first redistribution layer, and etching the photoresist layer to form spaced apart first and second TIV openings in the photoresist layer, where the first TIV opening is wider than the second TIV opening. The method can further include depositing a metal in the first and second TIV openings to form respective first and second TIV structures in contact with the metal line, removing the photoresist layer, forming a high-k dielectric on a top surface of the first and second TIV structures, and depositing a metal layer on the high-k dielectric layer to form respective first and second capacitors.

Some embodiments relate to a ferroelectric random access memory (FeRAM) device. The FeRAM device includes a bottom electrode structure and a top electrode overlying the ferroelectric structure. The top electrode has a first width as measured between outermost sidewalls of the top electrode. A ferroelectric structure separates the bottom electrode structure from the top electrode. The ferroelectric structure has a second width as measured between outermost sidewalls of the ferroelectric structure. The second width is greater than the first width such that the ferroelectric structure includes a ledge that reflects a difference between the first width and the second width. A dielectric sidewall spacer structure is disposed on the ledge and covers the outermost sidewalls of the top electrode.

A semiconductor device may include a semiconductor substrate and an isolation structure including a first dielectric layer formed over the semiconductor substrate, the first dielectric layer including one or more air gaps, and a first conductive structure formed on the dielectric layer, the conductive structure having a lower surface that faces the semiconductor substrate. Respective air gaps of the one or more air gaps of the first dielectric layer each may be disposed directly between corners of the lower surface of the conductive structure and the semiconductor substrate.

Semiconductor devices and methods are disclosed herein. In one example, a disclosed semiconductor device includes: an insulation layer, a first electrode with sidewalls and a bottom surface in contact with the insulation layer; a second electrode with sidewalls and a bottom surface in contact with the insulation layer; and an insulator formed between the first electrode and the second electrode. The insulator is coupled to a sidewall of the first electrode and coupled to a sidewall of the second electrode.