Exemplary methods of semiconductor processing may include providing a silicon-containing precursor to a processing region of a semiconductor processing chamber. The methods may include depositing a silicon-containing layer on surfaces defining the processing region of the semiconductor processing chamber. The methods may include forming a plasma of a hydrogen-containing precursor within the processing region of the semiconductor processing chamber. The methods may include depositing a silicon-containing material on a substrate disposed within the processing region of the semiconductor processing chamber.

Exemplary methods of semiconductor processing may include providing a silicon-containing precursor to a processing region of a semiconductor processing chamber. A substrate may be disposed within the processing region of the semiconductor processing chamber. The methods may include depositing a silicon-containing material on the substrate. The silicon-containing material may extend within the one or more recessed features along the substrate and a seam or void may be defined by the silicon-containing material within at least one of the one or more recessed features along the substrate. The methods may also include treating the silicon-containing material with a hydrogen-containing gas, such as plasma effluents of the hydrogen-containing gas, which may cause a size of the seam or void to be reduced.

Semiconductor device is provided. The semiconductor device includes a base substrate including a first region, a second region, and a third region arranged along a first direction, a first doped layer in the base substrate at the first region and a second doped layer in the base substrate at the third region, a first gate structure on the base substrate at the second region, a first dielectric layer on the base substrate coving the first doped layer, the second doped layer, and sidewalls of the first gate structure, first trenches in the first dielectric layer at the first region and the third region respectively, a first conductive layer in the first trenches, a second conductive layer on a surface of the first conductive layer at the second sub-regions after forming the first conductive layer, and a third conductive layer on the contact region of the first gate structure.

Methods and systems for forming a structure including a silicon carbide layer and structures formed using the methods and systems are disclosed. Exemplary methods include providing a silicon carbide precursor to the reaction chamber, forming a plasma within the reaction chamber to form an initially flowable, viscous silicon carbide material on a surface of the substrate, wherein the initially viscous carbon material becomes the silicon carbide layer. Exemplary methods can include use of a silicon carbide precursor that includes a carbon-carbon triple bond and/or use of a relatively low plasma power density (e.g., less than 3 W/cm.sup.2).

A method of forming a semiconductor structure includes forming a first pattern of alternating spacers of a first material and a second material on a semiconductor substrate, forming a second pattern of the alternating spacers of the first material and the second material by selectively removing at least a portion of at least one of one or more of the spacers of the first material and one or more of the spacers of the second material to form a remaining pattern of spacers of the first material and the second material on the semiconductor substrate, and transferring the second pattern of the spacers of the first material and the second material to the semiconductor substrate to form two or more fins in the semiconductor substrate by etching the semiconductor substrate selective to the first material and the second material.

A method for depositing a film to form an air gap within a semiconductor device is disclosed. An exemplary method comprises pulsing a metal halide precursor onto the substrate and pulsing an oxygen precursor onto a selective deposition surface. The method can be used to form an air gap to, for example, reduce a parasitic resistance of the semiconductor device.

Provided are methods and systems for providing silicon-containing films. The composition of the silicon-containing film can be controlled by the choice of the combination of precursors and the ratio of flow rates between the precursors. The silicon-containing films can be deposited on a substrate by flowing two different organo-silicon precursors to mix together in a reaction chamber. The organo-silicon precursors react with one or more radicals in a substantially low energy state to form the silicon-containing film. The one or more radicals can be formed in a remote plasma source.

A semiconductor device includes a source/drain region, a source/drain silicide layer formed on the source/drain region, and a first contact disposed over the source/drain silicide layer. The first contact includes a first metal layer, an upper surface of the first metal layer is at least covered by a silicide layer, and the silicide layer includes a same metal element as the first metal layer.

A method for forming a semiconductor device is provided. The method includes forming a semiconductor protruding structure over a substrate and surrounding the semiconductor protruding structure with an insulating layer. The method also includes forming a dielectric layer over the insulating layer. The method further includes partially removing the dielectric layer and insulating layer using a planarization process. As a result, topmost surfaces of the semiconductor protruding structure, the insulating layer, and the dielectric layer are substantially level with each other. In addition, the method includes forming a protective layer to cover the topmost surfaces of the dielectric layer. The method includes recessing the insulating layer after the protective layer is formed such that the semiconductor protruding structure and a portion of the dielectric layer protrude from a top surface of a remaining portion of the insulating layer.

Provides a method for adjusting a thermal field of silicon carbide single crystal growth, and steps comprise: (A) screening a silicon carbide source, and filling into a bottom of a graphite crucible; (B) placing a guide inside the graphite crucible; (C) placing a rigid heat conductive material on the guide, so that a gap between the guide and a crucible wall of the graphite crucible is reduced; (D) fixing a seed crystal on a top of the graphite crucible; (E) placing the graphite crucible equipped with the silicon carbide source and the seed crystal in an induction high-temperature furnace used by physical vapor transport method; (F) performing a silicon carbide crystal growth process; and (G) obtaining a silicon carbide single crystal.