A reactor system comprises a process chamber, a gas inlet, and a dispenser. The dispenser is coupled to the gas inlet. The dispenser controls a gas flow from a vial to the gas inlet. The vial includes a coating material that, when released inside the process chamber under operating conditions of the reaction system, coats an inner wall of the process chamber.

A reactor system comprises a process chamber, a gas inlet, and a dispenser. The dispenser is coupled to the gas inlet. The dispenser controls a gas flow from a vial to the gas inlet. The vial includes a coating material that, when released inside the process chamber under operating conditions of the reaction system, coats an inner wall of the process chamber.

The present inventive concept relates to a substrate processing device and a substrate processing method. The substrate processing device comprises: a chamber; a substrate support part rotatably installed in a process space inside the chamber so as to allow at least one substrate to be seated thereon; a first gas spray unit for spraying, to a first region of the process space, a source gas and a first purge gas for purging the source gas; a source gas supply source for supplying the source gas to the first gas spray unit; a first purge gas supply source for supplying the first purge gas to the first gas spray unit; a second gas spray unit spatially separated from the first region and configured to spray, to a second region of the process space, a reactant gas reacting with the source gas and a second purge gas for purging the reactant gas; a reactant gas supply source for supplying the reactant gas to the second gas spray unit; and a second purge gas supply source for supplying the second purge gas to the second gas spray unit.

The present inventive concept relates to a substrate processing device and a substrate processing method. The substrate processing device comprises: a chamber; a substrate support part rotatably installed in a process space inside the chamber so as to allow at least one substrate to be seated thereon; a first gas spray unit for spraying, to a first region of the process space, a source gas and a first purge gas for purging the source gas; a source gas supply source for supplying the source gas to the first gas spray unit; a first purge gas supply source for supplying the first purge gas to the first gas spray unit; a second gas spray unit spatially separated from the first region and configured to spray, to a second region of the process space, a reactant gas reacting with the source gas and a second purge gas for purging the reactant gas; a reactant gas supply source for supplying the reactant gas to the second gas spray unit; and a second purge gas supply source for supplying the second purge gas to the second gas spray unit.

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.

Provided in the present disclosure are a coating apparatus and an application thereof, being used for coating on the surface of a substrate, the coating apparatus comprises a feeding device and a device main body, wherein the feeding device is configured to communicate with the apparatus device main body, the feeding device comprises a gas feeding device and a liquid feeding device, the gas feeding device is in communication with the device main body and is used for transmitting a gaseous gas raw material to the device main body, the liquid feeding device is in communication with the device main body and is used for transmitting a liquid gasified gas raw material to the device main body, the device main body is used for preparing a thin film based on the gas raw material, and the same coating apparatus can be used for preparing various thin films or film layers with different properties or of different types on the surface of the substrate.

Provided in the present disclosure are a coating apparatus and an application thereof, being used for coating on the surface of a substrate, the coating apparatus comprises a feeding device and a device main body, wherein the feeding device is configured to communicate with the apparatus device main body, the feeding device comprises a gas feeding device and a liquid feeding device, the gas feeding device is in communication with the device main body and is used for transmitting a gaseous gas raw material to the device main body, the liquid feeding device is in communication with the device main body and is used for transmitting a liquid gasified gas raw material to the device main body, the device main body is used for preparing a thin film based on the gas raw material, and the same coating apparatus can be used for preparing various thin films or film layers with different properties or of different types on the surface of the substrate.

Localized stresses can be modulated in a film deposited on a bowed semiconductor substrate by selectively and locally curing the film by ultraviolet (UV) radiation. A bowed semiconductor substrate can be asymmetrically bowed. A UV-curable film is deposited on the front side or the backside of the bowed semiconductor substrate. A mask is provided between the UV-curable film and a UV source, where openings in the mask are patterned to selectively define exposed regions and non-exposed regions of the UV-curable film. Exposed regions of the UV-curable film modulate localized stresses to mitigate bowing in the bowed semiconductor substrate.

Localized stresses can be modulated in a film deposited on a bowed semiconductor substrate by selectively and locally curing the film by ultraviolet (UV) radiation. A bowed semiconductor substrate can be asymmetrically bowed. A UV-curable film is deposited on the front side or the backside of the bowed semiconductor substrate. A mask is provided between the UV-curable film and a UV source, where openings in the mask are patterned to selectively define exposed regions and non-exposed regions of the UV-curable film. Exposed regions of the UV-curable film modulate localized stresses to mitigate bowing in the bowed semiconductor substrate.

Provided by the invention disclosure is a coating equipment. The coating equipment comprises a reaction chamber body provided with a reaction chamber, a gas supply part configured to supply gas to the reaction chamber, a pumping device configured to communicate with the reaction chamber, a pulse power supply adapted to provide the reaction chamber body with a pulsed electric field and a radio frequency power supply adapted to provide the reaction chamber body with a radio frequency electric field, wherein the reaction chamber is adapted to accommodate a plurality of workpiece. When the pulse power supply and the radio frequency power supply are turned on, the gas in the reaction chamber body is ionized under the radio frequency electric field and the pulsed electric field to generate plasma, and the plasma is deposited on the surface of the workpieces.