The present disclosure relates to semiconductor structures and, more particularly, to an integrated thin film resistor with a metal-insulator-metal capacitor and methods of manufacture. The structure includes: a first buffer contact on a substrate; a second buffer contact on the substrate, the second buffer contact being on a same wiring level as the first buffer contact; a resistive film contacting the first buffer contact and the second buffer contact, the resistive film extending on the substrate between the first buffer contact and the second buffer contact; and electrical contacts landing on both the first buffer contact and the second buffer contact, but not directly contacting with the resistive film.

A CR snubber element includes a first resistance part, a first capacitance part, a second resistance part, and a second capacitance part. The first capacitance part is connected in series to the first resistance part. The second resistance part is connected in series to the first resistance part and the first capacitance part and the second capacitance part is connected in parallel to the second resistance part. The CR snubber element is configured such that the second resistance part is disconnected when the first capacitance part is short-circuited.

A method of making a semiconductor device, includes: providing a first dielectric layer; sequentially forming a first metal layer, a dummy capacitor dielectric layer, and a second metal layer over the first dielectric layer; and using a single mask layer with two patterns to simultaneously recess two portions of the second metal layer so as to define a metal thin film of a resistor and a top metal plate of a capacitor.

A method of making a semiconductor device, includes: providing a first dielectric layer; sequentially forming a first metal layer, a dummy capacitor dielectric layer, and a second metal layer over the first dielectric layer; and using a single mask layer with two patterns to simultaneously recess two portions of the second metal layer so as to define a metal thin film of a resistor and a top metal plate of a capacitor.

RC architectures are provided that include a substrate provided with a capacitor having a thin-film top electrode portion at a surface of the substrate on one side thereof. The resistance provided in series with the capacitor is controlled by providing a contact plate, spaced from the thin-film top electrode portion, and a set of plural bridging contacts extending between, and electrically interconnecting, the thin-film top electrode portion and the contact plate. Different resistance values can be set by appropriate selection of the number of bridging contacts. The capacitor can be a three-dimensional capacitor and contacts are then provided on respective first and second sides of the substrate, which face each other in the thickness direction of the substrate.

A semiconductor device that includes a semiconductor substrate; a first capacitance section on the semiconductor substrate, the first capacitance section including a first electrode layer, a first dielectric layer, and a second electrode layer; a second capacitance section on the semiconductor substrate, the second capacitance section including a third electrode layer, a second dielectric layer, and a fourth electrode layer; a first external electrode; a second external electrode; a first lead wire led out from the first capacitance section to the first external electrode and having an inductance L.sub.1; and a second lead wire led out from the second capacitance section to the second external electrode and having an inductance L.sub.2, wherein an electrostatic capacity C.sub.1 of the first capacitance section and an electrostatic capacity C.sub.2 of the second capacitance section are different, and L.sub.1/L.sub.2=0.8 to 1.2.

A capacitor structure includes a semiconductor substrate, a first vertical diffusion plate in the semiconductor substrate, a first STI structure in the semiconductor substrate and surrounding the first vertical diffusion plate, a second vertical diffusion plate in the semiconductor substrate and surrounding the first STI structure, and an ion well in the semiconductor substrate. The ion well is disposed directly under the first vertical diffusion plate, the first STI structure and the second vertical diffusion plate. The second vertical diffusion plate is electrically coupled to an anode of the capacitor structure. The first vertical diffusion plate is electrically coupled to a cathode of the capacitor structure.

According to various embodiments, an integrated circuit may include an upper inter-level dielectric (ILD) layer, a lower ILD layer, and an interlayer arranged between the upper ILD layer and the lower ILD layer. The integrated circuit may further include a capacitor device and a resistor device. The capacitor device may include a top plate disposed in a first region of the interlayer and a bottom plate disposed in the lower ILD layer. The resistor device may include a resistive element and a plurality of vias disposed in a second region of the interlayer. The plurality of vias may extend from the resistive element to the lower ILD layer. A distance between the top plate and the lower ILD layer may be at least substantially equal to a height of each via of the plurality of vias.

A capacitor structure includes a semiconductor substrate, a first vertical diffusion plate in the semiconductor substrate, a first STI structure in the semiconductor substrate and surrounding the first vertical diffusion plate, a second vertical diffusion plate in the semiconductor substrate and surrounding the first STI structure, and an ion well in the semiconductor substrate. The ion well is disposed directly under the first vertical diffusion plate, the first STI structure and the second vertical diffusion plate. The second vertical diffusion plate is electrically coupled to an anode of the capacitor structure. The first vertical diffusion plate is electrically coupled to a cathode of the capacitor structure.

The disclosure provides a semiconductor device that can reduce the area of the circuit elements formed thereon. The semiconductor device includes a first conductivity type region formed on a substrate and formed with a resistance element surrounded by an insulating film; a second conductivity type region laminated in contact with an upper surface of the resistance element; a capacitor formed on the resistance element via an interlayer insulating layer; a via electrically connecting a terminal of the resistance element and a terminal of the capacitor in series; and a power supply line and a ground line electrically connected to the other terminal of the resistance element and the other terminal of the capacitor respectively.