A method used in forming integrated circuitry comprises forming a stack comprising vertically-alternating first tiers and second tiers. The stack comprises a cavity therein that comprises a stair-step structure. At least a portion of sidewalls of the cavity is lined with sacrificial material. Insulative material is formed in the cavity radially inward of the sacrificial material. At least some of the sacrificial material is removed from being between the cavity sidewalls and the insulative material to form a void space there-between. Insulator material is formed in at least some of the void space. Other embodiments, including structure independent of method, are disclosed.

A gate insulator film made of silicon dioxide or gallium oxide is formed on a gallium nitride (GaN) substrate. The GaN substrate is preheated by irradiation with light from halogen lamps, and the surface of the substrate including the gate insulator film is heated to a high temperature for an extremely short time by irradiation with a flash of light from flash lamps. Heating the substrate surface including the gate insulator film in an extremely short heat treatment time prevents the desorption of nitrogen from GaN and makes it possible to reduce the traps existing at the interface between the gate insulator film and GaN without diffusing gallium into the gate insulator film.

The present disclosure relates to a semiconductor device includes a substrate and first and second spacers on the substrate. The semiconductor device includes a gate stack between the first and second spacers. The gate stack includes a gate dielectric layer having a first portion formed on the substrate and a second portion formed on the first and second spacers. The first portion includes a crystalline material and the second portion comprises an amorphous material. The gate stack further includes a gate electrode on the first and second portions of the gate dielectric layer.

A substrate processing method is described for forming a titanium nitride material that may be used for superconducting metallization or work function adjustment applications. The substrate processing method includes depositing by vapor phase deposition at least one monolayer of a first titanium nitride film on a substrate, and treating the first titanium nitride film with plasma excited hydrogen-containing gas, where the first titanium nitride film is polycrystalline and the treating increases the (200) crystallographic texture of the first titanium nitride film. The method further includes depositing by vapor phase deposition at least one monolayer of a second titanium nitride film on the treated at least one monolayer of the first titanium nitride film, and treating the at least one monolayer of the second titanium nitride film with plasma excited hydrogen-containing gas.

A method for preventing the collapse of patterned, high aspect ratio features formed in semiconductor substrates upon removal of an initial fluid of the type used to clean etch residues from the spaces between the features. In the present method, the spaces are at least partially filled with a displacement solution, such as via spin coating, to substantially displace the initial fluid. The displacement solution includes at least one solvent and at least one fill material in the form of a water-soluble polymer such as polyvinylpyrrolidone (PVP) or polyacrylamide (PAAM). The solvent is then volatized to deposit the fill material in substantially solid form within the spaces. The fill material may be removed by known plasma ash process via a high ash rate as compared to use of current fill materials, which prevents or mitigates silicon loss.

Provided are an electronic device including a dielectric layer having an adjusted crystal orientation and a method of manufacturing the electronic device. The electronic device includes a seed layer provided on a substrate and a dielectric layer provided on the seed layer. The seed layer includes crystal grains having aligned crystal orientations. The dielectric layer includes crystal grains having crystal orientations aligned in the same direction as the crystal orientations of the seed layer.

A treatment method is provided that includes an embedding step of embedding an organic film in an undercoat film in which a depression is formed; and an etching step of performing etching, after the embedding step, until at least a portion of a top of the undercoat film is exposed.

A system for processing semiconductor wafers, the system including: a processing chamber; a heat source; a substrate holder configured to expose a semiconductor wafer to the heat source; a first electrode configured to be detachably coupled to a first major surface of a semiconductor wafer; and a second electrode coupled to the substrate holder, the first electrode and the second electrode together configured to apply an electric field in the semiconductor wafer.

In an embodiment, a structure includes: a semiconductor substrate; a fin extending from the semiconductor substrate; a gate stack over the fin; an epitaxial source/drain region in the fin adjacent the gate stack; and a gate spacer disposed between the epitaxial source/drain region and the gate stack, the gate spacer including a plurality of silicon oxycarbonitride layers, each of the plurality of silicon oxycarbonitride layers having a different concentration of silicon, a different concentration of oxygen, a different concentration of carbon, and a different concentration of nitrogen.

The present disclosure provides a semiconductor device, including a substrate, a fin over the substrate, a multilayer gate dielectric stack over the fin, wherein the multilayer gate dielectric stack includes a first ferroelectric layer, and a first dielectric layer coupled to the first ferroelectric layer, and a gate over the multilayer gate dielectric stack.