A film deposition device according to the present embodiment includes a chamber. A mounting part is provided in the chamber to allow a substrate to be placed thereon and contains aluminum nitride. A heater is provided in the mounting part. A supply part is configured to supply a process gas for film deposition to the substrate on the mounting part in the chamber. A cover film covers a mounting surface of the mounting part on which the substrate is placed, a back surface opposite to the mounting surface, and a side surface between the mounting surface and the back surface and contains yttrium oxide.

A system and method for cleaning a preclean process chamber in between wafer processing. The internal pressure of the preclean process chamber is reduced to a first pressure and a first gas that consists of oxygen and an inert or noble gas, is introduced into the chamber. Plasma is generated within the preclean process chamber using the first gas at the first pressure. Internal pressure is then reduced to a second pressure, less than the first, and the first gas is continued into the chamber. Plasma is then generated using the first gas at the second pressure. Thereafter, a second gas, consisting of an oxygen-free inert or noble gas, is introduced into the chamber at the second pressure, following which plasma is generated within the chamber using only the second gas.

There is provided a technique of cleaning an inside of a process container, including: (a) removing substances adhered in a process container set at a first temperature by supplying a first gas at a first flow rate into the process container and exhausting the inside of the process container; (b) physically desorbing and removing residual fluorine in the process container set at a second temperature by supplying a second gas at a second flow rate into the process container and exhausting the inside of the process container; and (c) chemically desorbing and removing residual fluorine in the process container set at a third temperature by supplying a third gas at a third flow rate into the process container and exhausting the inside of the process container.

There is provided a technique that includes: (a) lowering a temperature in a process chamber supplied with a cleaning gas containing a halogen element while being heated to a first temperature, from the first temperature to a second temperature equal to or lower than a temperature at which substrate processing is performed in the process chamber, while vacuum-exhausting an inside of the process chamber; and (b) after (a), supplying a gas containing a water vapor into the process chamber while vacuum-exhausting the inside of the process chamber, to cause the halogen element remaining in the process chamber to react with the water vapor.

A processing apparatus is provided. The processing apparatus includes a processing chamber, a pump, and an intersecting module. The process chamber has a gas outlet. The pump communicates with the gas outlet. The pump is configured to exhaust gas from the processing chamber via the gas outlet. The intersecting module is positioned between the pump and the gas outlet. The intersecting module includes a plurality of support members and a plurality of internal ventilating plates. The support members are arranged along a longitudinal direction. Each of the internal ventilating plates has a plurality of orifices. At least one of the internal ventilating plates is positioned between two of the support members positioned adjacent to each other in the longitudinal direction. Each of the internal ventilating plates is inclined relative to a transversal direction that is perpendicular to the longitudinal direction.

A chemical vapor deposition furnace for depositing silicon nitride films is disclosed. The furnace having a process chamber elongated in a substantially vertical direction and a wafer boat for supporting a plurality of wafers in the process chamber. A process gas injector inside the process chamber is provided with a plurality of vertically spaced gas injection holes to provide gas introduced at a feed end in an interior of the process gas injector to the process chamber. A valve system connected to the feed end of the process gas injector is being constructed and arranged to connect a source of a silicon precursor and a nitrogen precursor to the feed end for depositing silicon nitride layers. The valve system may connect the feed end of the process gas injector to a cleaning gas system to provide a cleaning gas to remove silicon nitride from the process gas injector and/or the processing chamber.

Exemplary methods of treating a chamber may include delivering a cleaning precursor to a remote plasma unit. The methods may include forming a plasma of the cleaning precursor. The methods may include delivering plasma effluents of the cleaning precursor to a processing region of a semiconductor processing chamber. The processing region may be defined by one or more chamber components. The one or more chamber components may include an oxide coating. The methods may include halting delivery of the plasma effluents. The methods may include treating the oxide coating with a hydrogen-containing material delivered to the processing region subsequent halting delivery of the plasma effluents.

A substrate processing apparatus is disclosed. Exemplary substrate processing apparatus includes a reaction chamber; a remote plasma unit; a cleaning gas lines configured to fluidly couple the remote plasma unit to the reaction chambers ; and a chamber liner disposed in a sidewall of the reaction chamber; wherein the cleaning gas line is connected to the sidewall of the reaction chamber through a cleaning gas opening; wherein the chamber liner is provided with a plurality of holes, being fluidly coupled to the cleaning gas opening.

Embodiments of a gas distribution plate for distributing gas in a processing chamber are provided. In one embodiment, a gas distribution plate includes a diffuser plate having an upstream side and a downstream side, and a plurality of gas passages passing between the upstream and downstream sides of the diffuser plate. At least one of the gas passages has a cylindrical shape for a portion of its length extending from the upstream side and a coaxial conical shape for the remainder length of the diffuser plate, the upstream end of the conical portion having substantially the same diameter as the cylindrical portion and the downstream end of the conical portion having a larger diameter.

A component, a method of manufacturing a component, and a method of cleaning a component is provided. The component includes a gas flow system within the component, wherein the gas flow system fluidly couples one or more inlet holes and one or more outlet holes. The manufacturing of the component results in an arc shaped groove and a circumferential groove created in the body of the ring. The component undergoes one or more cleaning operations, including rinsing, baking, or purging operations. The cleaning operations remove debris or particles in or on the component, where the debris or particles can be caused during manufacturing of the component, or during use of the component in a semiconductor processing system.