Abstract: Methods of forming a metal resistor are provided. The methods may include: depositing a metal layer, e.g., tungsten, on a substrate; and forming the metal resistor by implanting a semiconductor species, e.g., silicon and/or germanium, into the metal layer to form a semiconductor-metal alloy layer from at least a portion of the metal layer. In certain embodiments, an adhesion layer may be deposited by ALD prior to metal layer depositing. The metal resistor has a sheet resistance that remains substantially constant prior to and after subsequent annealing.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a corrosion and/or etch protection layer for contacts and interconnect metallization integration structures and methods of manufacture. The structure includes a metallization structure formed within a trench of a substrate and a layer of cobalt phosphorous (CoP) on the metallization structure. The CoP layer is structured to prevent metal migration from the metallization structure and corrosion of the metallization structure during etching processes.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to a corrosion and/or etch protection layer for contacts and interconnect metallization integration structures and methods of manufacture. The structure includes a metallization structure formed within a trench of a substrate and a layer of cobalt phosphorous (CoP) on the metallization structure. The CoP layer is structured to prevent metal migration from the metallization structure and corrosion of the metallization structure during etching processes.

Abstract: One aspect of the disclosure relates to a method of forming an integrated circuit structure. The method may include: forming a first work function metal over a set of fins having at least a first fin and a second fin; implanting the first work function metal with a first species; removing the implanted first work function metal from over the first fin such that a remaining portion of the implanted first work function metal remains over the second fin; forming a second work function metal over the set of fins including over the remaining portion of the implanted first work function metal; implanting the second work function metal with a second species; and forming a metal over the implanted second work function metal over the set of fins thereby forming the gate stack.

Abstract: One aspect of the disclosure relates to a method of forming an integrated circuit structure. The method may include: forming a first work function metal over a set of fins having at least a first fin and a second fin; implanting the first work function metal with a first species; removing the implanted first work function metal from over the first fin such that a remaining portion of the implanted first work function metal remains over the second fin; forming a second work function metal over the set of fins including over the remaining portion of the implanted first work function metal; implanting the second work function metal with a second species; and forming a metal over the implanted second work function metal over the set of fins thereby forming the gate stack.

Abstract: Methods of forming a semiconductor fin and methods for controlling dopant diffusion to a semiconductor fin are disclosed herein. The methods provide alternative ways to incorporate a carbon dopant into the fin to later control out-diffusion of dopants from a dopant-including epitaxial layer. One method includes depositing a carbon-containing layer over a portion of the fin adjacent to the gate and annealing to diffuse carbon from the carbon-containing layer into at least the portion of the semiconductor fin. This method can be applied to SOI or bulk semiconductor substrates. Another method includes epitaxially growing a carbon dopant containing semiconductor layer for later use in forming the fin.

Abstract: Methods of forming a metal resistor are provided. The methods may include: depositing a metal layer, e.g., tungsten, on a substrate; and forming the metal resistor by implanting a semiconductor species, e.g., silicon and/or germanium, into the metal layer to form a semiconductor-metal alloy layer from at least a portion of the metal layer. In certain embodiments, an adhesion layer may be deposited by ALD prior to metal layer depositing. The metal resistor has a sheet resistance that remains substantially constant prior to and after subsequent annealing.

Abstract: One aspect of the disclosure relates to a contact within a dielectric layer to a source/drain terminal of a field-effect-transistor (FET). The contact may include: a titanium-tantalum-silicide at a surface of the source/drain terminal; a barrier layer over the titanium-tantalum-silicide; and a metal over the barrier layer and extending to a top surface of the dielectric layer.

Abstract: Methods are presented to monitor the performance of an ion implanter such as the E500. Ion implantation typically involves physical processes performed on a wafer such as rotation, tilt, and twist. These methods generate particulate contaminants (PCs) that affect the kill rate of the semiconductor devices on the wafer. Variations in tilt angle also compromise dose accuracy. Presently, methods for testing for PCs and implant dose accuracy do not simulate actual manufacturing conditions. This invention discloses methods to test PC buildup using multiple wafers that are subjected to rotation, twist, tilt, and combinations thereof. Additionally, methods to test dose accuracy are presented, involving implanting a monitor wafer at an angle where the crystalline channel is aligned with the ion beam. Measuring sheet resistance as a function of tilt angle at this point ensures accurate tilt-angle calibration of the ion implanter.