A method of concurrently forming source/drain contacts (CAs) and gate contacts (CBs) and device are provided. Embodiments include forming metal gates (PC) and source/drain (S/D) regions over a substrate; forming an ILD over the PCs and S/D regions; forming a mask over the ILD; concurrently patterning the mask for formation of CAs adjacent a first portion of each PC and CBs over a second portion of the PCs; etching through the mask, forming trenches extending through the ILD down to a nitride capping layer formed over each PC and a trench silicide (TS) contact formed over each S/D region; selectively growing a metal capping layer over the TS contacts formed over the S/D regions; removing the nitride capping layer from the second portion of each PC; and metal filling the trenches, forming the CAs and CBs.

In various embodiments a method for manufacturing a metallization layer on a substrate is provided, wherein the method may include providing a structured layer of a catalyst material on the substrate, the catalyst material may include a first layer of material arranged over the substrate and a second layer of material arranged over the first layer of material, wherein the structured layer of catalyst material having a first set of regions including the catalyst material over the substrate and a second set of regions free of the catalyst material over the substrate, and forming a plurality of groups of nanotubes over the substrate, each group of the plurality of groups of nanotubes includes a plurality of nanotubes formed over a respective region in the first set of regions.

A semiconductor device and a process of forming the semiconductor device are disclosed. The semiconductor device type of a high electron mobility transistor (HEMT) has double SiN films on a semiconductor layer, where the first SiN film is formed by the lower pressure chemical vapor deposition (LPCVD) technique, while, the second SiN film is deposited by the plasma assisted CVD (p-CVD) technique. Moreover, the gate electrode has an arrangement of double metals, one of which contains nickel (Ni) as a Schottky metal, while the other is free from Ni and covers the former metal. A feature of the invention is that the first metal is in contact with the semiconductor layer but apart from the second SiN film.

Semiconductor structures having a source contact and a drain contact that exhibit reduced contact resistance and methods of forming the same are disclosed. In one embodiment of the present application, the reduced contact resistance is provided by forming a layer of a dipole metal or metal-insulator-semiconductor (MIS) oxide between an epitaxial semiconductor material (providing the source region and the drain region of the device) and an overlying metal semiconductor alloy. In yet other embodiment, the reduced contact resistance is provided by increasing the area of the source region and drain region by patterning the epitaxial semiconductor material that constitutes at least an upper portion of the source region and drain region of the device.

Generally, the present disclosure provides example embodiments relating to formation of a gate structure of a device, such as in a replacement gate process, and the device formed thereby. In an example method, a gate dielectric layer is formed over an active area on a substrate. A dummy layer that contains a passivating species (such as fluorine) is formed over the gate dielectric layer. A thermal process is performed to drive the passivating species from the dummy layer into the gate dielectric layer. The dummy layer is removed. A metal gate electrode is formed over the gate dielectric layer. The gate dielectric layer includes the passivating species before the metal gate electrode is formed.

A method for manufacturing an interconnect structure includes providing a substrate structure including a substrate, a first metal layer on the substrate, a dielectric layer on the substrate and covering the first metal layer, and an opening extending to the first metal layer; forming a first barrier layer on a bottom and sidewalls of the opening with a first substrate bias; forming a second barrier layer on the first barrier layer with a second substrate bias, the second substrate bias being greater than the first substrate bias, the first and second barrier layers forming collectively a barrier layer; removing a portion of the barrier layer on the bottom and on the sidewalls of the opening by bombarding the barrier layer with a plasma with a vertical substrate bias; and forming a second metal layer filling the opening.

Provided are a metal chalcogenide thin film and a method and device for manufacturing the same. The metal chalcogenide thin film includes a transition metal element and a chalcogen element, and at least one of the transition metal element and the chalcogen element having a composition gradient along the surface of the metal chalcogenide thin film, the composition gradient being an in-plane composition gradient. The metal chalcogenide thin film may be prepared by using a manufacturing method including providing a transition metal precursor and a chalcogen precursor on a substrate by using a confined reaction space in such a manner that at least one of the transition metal precursor and the chalcogen precursor forms a concentration gradient according to a position on the surface of the substrate; and heat-treating the substrate.

In a method of manufacturing a semiconductor memory device, a plurality of first conductive structures including a first conductive pattern and a hard mask are sequentially stacked on a substrate. A plurality of preliminary spacer structures including first spacers, sacrificial spacers and second spacers are sequentially stacked on sidewalls of the conductive structures. A plurality of pad structures are formed on the substrate between the preliminary spacer structures, and define openings exposing an upper portion of the sacrificial spacers. A first mask pattern is formed to cover surfaces of the pad structures, and expose the upper portion of the sacrificial spacers. The sacrificial spacers are removed to form first spacer structures having respective air spacers, and the first spacer structures include the first spacers, the air spacers and the second spacers sequentially stacked on the sidewalls of the conductive structures.

Metal spacer-based approaches for fabricating conductive lines/interconnects are described. In an example, an integrated circuit structure includes a substrate. A first spacer pattern is on the substrate, the first spacer pattern comprising a first plurality of dielectric spacers and a first plurality of metal spacers formed along sidewalls of the first plurality of dielectric spacers, wherein the first plurality of dielectric spacers have a first width (W1). A second spacer pattern is on the substrate, where the second spacer pattern interleaved with the first spacer pattern, the second spacer pattern comprising a second plurality of dielectric spacers having a second width (W2) formed on exposed sidewalls of the first plurality of metal spacers, and a second plurality of metal spacers formed on exposed sidewalls of the second plurality of dielectric spacers.

There is provided a technique that includes: (a) supplying a molybdenumcontaining gas containing molybdenum and oxygen to a substrate in a process chamber; (b) supplying an additive gas containing hydrogen to the substrate; and (c) supplying a reducing gas containing hydrogen and having a chemical composition different from that of the additive gas to the substrate, wherein at least two of (a), (b), and (c) are performed simultaneously or to partially overlap with each other in time one or more times or (a), (b), and (c) are performed sequentially one or more times to form a molybdenum film on the substrate.