A method of forming a carbon hard mask includes generating a radio frequency plasma including carbon-based ions by supplying continuous wave radio frequency power to a plasma processing chamber. The carbon-based ions have a first average ion energy. The method further includes adjusting the first average ion energy of the carbon-based ions to a second average ion energy by supplying continuous wave direct current power to the plasma processing chamber concurrently with the continuous wave radio frequency power and forming a carbon hard mask at a substrate within the plasma processing chamber by delivering the carbon-based ions having the second average ion energy to the substrate.

A method includes etching a semiconductor substrate to form a trench, and depositing a dielectric layer using an Atomic Layer Deposition (ALD) cycle. The dielectric layer extends into the trench. The ALD cycle includes pulsing Hexachlorodisilane (HCD) to the semiconductor substrate, purging the HCD, pulsing triethylamine to the semiconductor substrate, and purging the triethylamine. An anneal process is then performed on the dielectric layer.

A patterned backside stress compensation film having different stress in different sectors is formed on a backside of a substrate to reduce combination warpage of the substrate. The film can be formed by employing a radio frequency electrode assembly including plurality of conductive plates that are biased with different RF power and cause local variations in the plasma employed to deposit the backside film. Alternatively, the film may be deposited with uniform stress, and some of its sectors are irradiated with ultraviolet radiation to change the stress of these irradiated sectors. Yet alternatively, multiple backside deposition processes may be sequentially employed to deposit different backside films to provide a composite backside film having different stresses in different sectors.

A patterned backside stress compensation film having different stress in different sectors is formed on a backside of a substrate to reduce combination warpage of the substrate. The film can be formed by employing a radio frequency electrode assembly including plurality of conductive plates that are biased with different RF power and cause local variations in the plasma employed to deposit the backside film. Alternatively, the film may be deposited with uniform stress, and some of its sectors are irradiated with ultraviolet radiation to change the stress of these irradiated sectors. Yet alternatively, multiple backside deposition processes may be sequentially employed to deposit different backside films to provide a composite backside film having different stresses in different sectors.

The present disclosure generally relates to a substrate processing chamber, a substrate processing apparatus, and a substrate processing method for self-assembled monolayer (SAM) deposition of low vapor pressure organic molecules (OM) followed by further substrate processing, such as atomic layer deposition.

The present disclosure relates to a mask for manufacturing a display. A mask for display according to the embodiment of the present disclosure comprises an aperture corresponding to a display area, a dummy aperture near the aperture, a rib surrounding circumferences of the aperture and the dummy aperture, and a sub rib between the aperture and the dummy aperture.

A method of coating an interior surface of a housing defining a volume includes partitioning the volume into a first zone and a second zone, the first zone isolated from fluid communication with the second zone; introducing one or more reactant gases, plasma, ions, or a combination thereof to the first zone and the second zone; and forming one or more coating layers on all or a portion of the interior surface within the first and second zones via reaction of the reactant gases, the plasma, or the combination thereof. A device for coating an interior surface of a housing is also provided.

A mask frame includes a first horizontal portion, a second horizontal portion disposed under the first horizontal portion, at least one vertical portion connecting the first horizontal portion and the second horizontal portion and a tensile bar coupled to the first horizontal portion, and the tensile bar is configured to apply a contraction force to the first horizontal portion in a longitudinal direction of the tensile bar.

Methods for depositing boron-containing films on a substrate are described. The substrate is exposed to a boron precursor and a plasma to form the boron-containing film (e.g., elemental boron, boron oxide, boron carbide, boron silicide, boron nitride). The exposures can be sequential or simultaneous. The boron-containing films are selectively deposited on one material (e.g., SiN or Si) rather than on another material (e.g., silicon oxide).

A method of fabricating a visible spectrum optical component includes: providing a substrate; forming a resist layer over a surface of the substrate; patterning the resist layer to form a patterned resist layer defining openings exposing portions of the surface of the substrate; performing deposition to form a dielectric film over the patterned resist layer and over the exposed portions of the surface of the substrate, wherein a top surface of the dielectric film is above a top surface of the patterned resist layer; removing a top portion of the dielectric film to expose the top surface of the patterned resist layer and top surfaces of dielectric units within the openings of the patterned resist layer; and removing the patterned resist layer to retain the dielectric units over the substrate.