A semiconductor device includes a first terminal, a second terminal positioned away from the first terminal, a first resistive segment coupled between the first terminal and the second terminal, a third terminal positioned away from the first terminal and the second terminal, a second resistive segment coupled between the second terminal and third terminal, a first floating plate disposed physically proximate the first resistive segment and including a first end coupled to one of the first terminal and the second terminal, and a second floating plate disposed physically proximate the second resistive segment and including a first end coupled to one of the second terminal and the third terminal.

Capacitor structures are provided. A capacitor structure includes a first metal line, a second metal line, a plurality of first capacitor cells coupled in parallel between the first metal line and the second metal line, and a plurality of second capacitor cells coupled in parallel between the first metal line and the second metal line. Each of the first capacitor cells includes a first bottom electrode coupled to the first metal line, a first dielectric material over the first bottom electrode, and a first top electrode over the first dielectric material and coupled to the second metal line. Each of the second capacitor cells includes a second bottom electrode coupled to the second metal line, a second dielectric material over the second bottom electrode, and a second top electrode over the second dielectric material and coupled to the first metal line.

Provided are a dielectric material and a device including the dielectric material. The dielectric material includes (K.sub.0.5Na.sub.0.5)NbO.sub.3 and (K.sub.0.5A.sub.0.5)TiO.sub.3, wherein A is a trivalent element having 3 valence electrons, in a solid solution; and the device includes a plurality of electrodes; and at least one dielectric layer between the plurality of electrodes, wherein the dielectric layers include the dielectric material.

A capacitor structure, including a transistor structure, a first metal conductive structure and a second metal conductive structure, is provided. The transistor structure includes a first ladder-shaped frame of a polycrystalline silicon layer and multiple first metal strips of a first metal layer. The first ladder-shaped frame is electrically isolated from the multiple first metal strips, and encircles a part of the multiple first metal strips. The first ladder-shaped frame forms a gate of the transistor structure. The multiple first metal strips form a drain and a source of the transistor structure. The first metal conductive structure is substantially overlapped with the first ladder-shaped frame. The second metal conductive structure is electrically connected to the multiple first metal strips, in which the second metal conductive structure is disposed across and electrically isolated from the first ladder-shaped frame and the first metal conductive structure.

Embodiments relate to the field of semiconductors, and provide a semiconductor structure and a method for fabricating the same. The semiconductor structure includes a first wafer and a second wafer. A surface of the first wafer has a first electrode plate, a first dielectric layer and a first dummy pad stacked in sequence to constitute a capacitor; and the surface of the first wafer further has a first functional pad, and the first functional pad and the first dummy pad are arranged on a same layer. The second wafer is bonded to the first wafer, and a surface of the second wafer has a second dummy pad and a second functional pad arranged on a same layer. The first dummy pad is bonded to the second dummy pad, and the first functional pad is bonded to the second functional pad.

An electronic device includes a multilevel lamination structure having a core layer, dielectric layers and conductive features formed in metal layers on or between respective ones or pairs of the dielectric layers. The core layer and the dielectric layers extend in respective planes of orthogonal first and second directions and are stacked along an orthogonal third direction. The conductive features include a first patterned conductive feature having multiple conductive turns in each of a first pair of the metal layers to form a first winding having a first turn and a final turn adjacent to one another in the same metal layer of the first pair, and a second patterned conductive feature having multiple conductive turns in a second pair of the metal layers to form a second winding having a first turn and a final turn.

An integrated circuit (IC) device includes a lower electrode including a first metal, a dielectric film on the lower electrode, and a conductive interface layer between the lower electrode and the dielectric film. The conductive interface layer includes a metal oxide film including at least one metal element. An upper electrode including a second metal is opposite the lower electrode, with the conductive interface layer and the dielectric film therebetween. To manufacture an IC device, an electrode including a metal is formed adjacent to an insulating pattern on a substrate. A conductive interface layer including a metal oxide film including at least one metal element is selectively formed on a surface of the electrode. A dielectric film is formed to be in contact with the conductive interface layer and the insulating pattern.

The present disclosure provides a capacitor, a semiconductor device, and a method for preparing a capacitor. The semiconductor device includes a plurality of memory cells, at least one of the memory cells including a capacitor. The capacitor includes a first electrode comprising titanium nitride and disposed on a substrate, a dielectric film disposed on the first electrode, a multilayer film disposed on the dielectric film, and a second electrode comprising titanium nitride and disposed on the multilayer film. The method for preparing the capacitor includes forming the first electrode comprising titanium nitride on the substrate, forming a dielectric film on the first electrode, forming the multilayer film on the dielectric film, and forming the second electrode comprising titanium nitride on the multilayer film.

In a described example, a method of forming a capacitor includes forming a doped polysilicon layer over a semiconductor substrate. The method also includes forming a dielectric layer on the doped polysilicon layer. The method also includes forming an undoped polysilicon layer on the dielectric layer.

A method of operating a mechanical switching device is disclosed. The switching device includes a housing, an assembly disposed in the housing, and a body. The assembly is thermally deformable and comprises a beam held in two different places by two arms secured to edges of the housing. The beam is remote from the body in a first configuration and in contact with and immobilized by the body in a second configuration. The assembly has the first configuration at a first temperature and the second configuration when one of the arms has a second temperature different from the first temperature. The method includes exposing an arm of the assembly to the second temperature, and releasing the beam using a release mechanism. The release mechanism includes a pointed element comprising a pointed region directed towards the body. The pointed element limits an open crater in a concave part of a projection.