Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

A device includes a dielectric layer, an interlayer metal pad in the dielectric layer, a first capacitor over the interlayer metal pad, and a second capacitor over the dielectric layer. The first capacitor includes a first bottom capacitor electrode over and in contact with the interlayer metal pad, a first top capacitor electrode, and a first inter-electrode dielectric layer between the first bottom capacitor electrode and the first top capacitor electrode. The second capacitor includes a second bottom capacitor electrode over and in contact with the dielectric layer, a second top capacitor electrode, and a second inter-electrode dielectric layer between the second bottom capacitor electrode and the second top capacitor electrode.

Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

An integrated resistor-capacitor (RC) structure (400) is disclosed. The integrated RC structure includes a vertical capacitor (302,402,306) and a resistive element (308,310) disposed above the capacitor. The integrated RC structure uses a low ohmic substrate (302) to ensure a good ground return path for the capacitor. Further, a resistivity of the substrate is configured such that a top plate (306) of the capacitor provides a reference ground above a predefined frequency. The impedance of the resistive element (308,310) is matched, relative to the reference ground, to a predetermined resistance. As such, the resistance of the resistive element (308,310) can be controlled to provide an impedance controlled RC structure over a range of operating frequencies.

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.

Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

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.

In an electrical circuit arrangement, which is formed by an RC-snubber element monolithically integrated into a semiconductor substrate, a first capacitor and a resistor of the RC-snubber element are vertically formed in a semiconductor region of a first type of doping of the semiconductor substrate. At least one further capacitor is connected in series with the first capacitor. The further capacitor is integrated laterally with the first capacitor in a semiconductor region of a second type of doping, which adjoins the semiconductor region of the first type of doping, and by virtue of the different type of doping electrically insulates the further capacitor from the semiconductor region of the first type of doping. This circuit arrangement forms a low inductance RC-snubber element with high dielectric strength, which has high heat dissipation and integration density.

A system and method for fabricating metal insulator metal capacitors while managing semiconductor processing yield and increasing capacitance per area are described. A semiconductor device fabrication process places an oxide layer on top of a metal layer. A photoresist layer is formed on top of the oxide layer and etched with repeating spacing. One of a variety of lithography techniques is used to alter the distance between the spacings. The process etches trenches into areas of the oxide layer unprotected by the photoresist layer and strips the photoresist layer. The top and bottom corners of the trenches are rounded. The process deposits a bottom metal, a dielectric, and a top metal on the oxide layer both on areas with the trenches and on areas without the trenches. The process completes the metal insulator metal capacitor with metal nodes contacting each of the top plate and the bottom plate.