Exemplary methods of manufacturing a semiconductor cover wafer may include sintering aluminum nitride particles into a substrate characterized by a thickness and characterized by a disc shape. The methods may include grinding a surface of the substrate to reduce the thickness to less than or about 2 mm. The methods may include polishing the surface of the substrate to reduce a roughness. The methods may include annealing the substrate at a temperature of greater than or about 800° C. for a time period of greater than or about 60 minutes.

A film forming method includes repeatedly performing: forming a film on one substrate or consecutively on a plurality of substrates by supplying a film formation gas into a processing container while heating the substrate on a stage; cleaning an interior of the processing container by a fluorine-containing gas by setting a temperature of the stage to a first temperature at which a vapor pressure of an aluminum fluoride becomes lower than a control pressure in the processing container in a state in which the substrate is unloaded from the processing container; and performing a precoating continuously to the cleaning the interior of the processing container such that a precoat film is formed on at least a surface of the stage by setting the temperature of the stage to a second temperature at which the vapor pressure of the aluminum fluoride becomes lower than the control pressure in the processing container.

A CVD apparatus includes a chamber, a susceptor, an entry/takeout port for a substrate, and a gate valve provided at the entry/takeout port, in which the susceptor has a mounting plate and a support, the entry/takeout port is provided on a part of a side of the chamber, and is provided in a range from an inner bottom surface of the chamber to a position corresponding to the lower surface of the mounting plate when the susceptor is located at an upper end in the vertical direction, and the inner bottom surface of the chamber, the range from the inner bottom surface of the chamber to the position corresponding to the lower surface of the mounting plate when the susceptor is located at the upper end in the vertical direction, the lower surface of the mounting plate, and the outer side surface of the support are coated with ceramic liners.

A gas delivery system includes a 2-port valve including a first valve located between a first port and a second port. A 4-port valve includes a first node connected to a first port and a second port. A bypass path is located between the third port and the fourth port. A second node is located along the bypass path. A second valve is located between the first node and the second node. A manifold block defines gas flow channels configured to connect the first port of the 4-port valve to a first inlet, configured to connect the second port of the 4-port valve to the first port of the 2-port valve, the third port of the 4-port valve to a second inlet, the second port of the 2-port valve to a first outlet, and the fourth port of the 4-port valve to a second outlet.

According to an embodiment of the present disclosure, a thin film forming apparatus includes a chamber, a plurality of gas inlets that are formed at an upper portion of the chamber and receive at least two reaction gas and precursors for radical reaction, and a radical unit configured to generate radicals by reacting the reaction gas provided through the gas inlet and deposit a thin film on a substrate by spraying the radicals and the precursors downward. The radical unit is configured with a plurality of plates, a precursor spray path is configured to be sprayed from the radical unit after the precursors are sprayed to a plurality of paths greater than precursor spray paths of the gas inlet in an uppermost plate among the plurality of plates, and a reaction gas spray path is configured not to overlap with the precursor spray path.

A film forming method of forming a film on a substrate by using a film forming apparatus including a processing container, and a stage provided in an interior of the processing container to place the substrate thereon and in which aluminum is contained, includes: forming a film continuously on one substrate or on a plurality of substrates by supplying a gas for film formation to the interior of the processing container while heating the substrate placed on the stage; cleaning the interior of the processing container with a fluorine-containing gas in a state in which the substrate is unloaded from the processing container; and performing a post-process by generating plasma of an oxygen- and hydrogen-containing-gas in the interior of the processing container, wherein the forming the film, the cleaning the interior of the processing container, and the performing the post-process are repeatedly performed.

Systems and methods may be used to produce coated components. Exemplary semiconductor chamber components may include an aluminum alloy comprising nickel and may be characterized by a surface. The surface may include a corrosion resistant coating. The corrosion resistant coating may include a conformal layer and a non-metal layer. The conformal layer may extend about the semiconductor chamber component. The non-metal oxide layer may extend over a surface of the conformal layer. The non-metal oxide layer may be characterized by an amorphous microstructure having a hardness of from about 300 HV to about 10,000 HV. The non-metal oxide layer may also be characterized by an sp.sup.2 to sp.sup.3 hybridization ratio of from about 0.01 to about 0.5 and a hydrogen content of from about 1 wt. % to about 35 wt. %.

A semiconductor processing system includes a gas delivery module, and a chamber body connected to the gas delivery module. The divider has an aperture, is fixed within an interior of the chamber body, and separates an interior of the chamber body into upper and lower chambers, the aperture fluidly coupling the lower chamber to the upper chamber. A susceptor is arranged within the aperture. A controller is operably connected to the gas delivery module to purge the lower chamber with a first purge flow including an etchant while etching the upper chamber, purge the lower chamber with a second purge flow including the etchant while depositing a precoat in the upper chamber, and purge the lower chamber with a third purge flow including the etchant while depositing a film onto a substrate in the upper chamber. Film deposition methods and lower chamber etchant purge kits are also described.

According to an aspect of the invention, there is provided a plasma-resistant member including: a base member; and a layer structural component formed at a surface of the base member, the layer structural component including an yttria polycrystalline body and being plasma resistant, the layer structural component including a first uneven structure, and a second uneven structure formed to be superimposed onto the first uneven structure, the second uneven structure having an unevenness finer than an unevenness of the first uneven structure.

There is provided a processing apparatus for forming a film with a plasma. The processing apparatus comprises: a processing container, having a ceramic sprayed coating on an inner wall on which an antenna that radiates microwaves is arranged, configured to accommodate a substrate; a mounting table configured to mount the substrate in the processing container; and a controller configured to perform a precoating process of coating a surface of the ceramic sprayed coating with a first carbon film with a plasma of a first carbon-containing gas at a first pressure and a film forming process of forming a second carbon film on the substrate with a plasma of a second carbon-containing gas at a second pressure.