Abstract: A method for forming a plasma resistant ceramic coating on an article includes placing the article into a chamber or spray cell of a plasma spraying system. A ceramic powder is then fed into the plasma spraying system at a powder feed rate, and a plasma resistant ceramic coating is deposited onto at least one surface of the article in a plasma spray process by the plasma spray system. The plasma spray system is then used to perform an in-situ plasma flame heat treatment of the plasma resistant ceramic coating to form crust on the plasma resistant ceramic coating.

Abstract: A chamber component comprises a body, a first protective layer and a conformal second protective layer over the first protective layer. The first protective layer comprises a plasma resistant ceramic, has a thickness of greater than approximately 50 microns and comprises a plurality of cracks and pores. The conformal second protective layer comprises a plasma resistant rare earth oxide, has a thickness of less than 50 microns, has a porosity of less than 1%, and seals the plurality of cracks and pores of the first protective layer.

Abstract: Embodiments of the present disclosure relate to articles, coated articles and methods of coating such articles with a rare earth metal containing fluoride coating. The coating can contain at least a first metal (e.g., a rare earth metal, tantalum, zirconium, etc.) and a second metal that have been co-deposited onto a surface of the article. The coating can include a homogenous mixture of the first metal and the second metal and does not contain mechanical segregation between layers in the coating.

Abstract: Embodiments of the present disclosure relate to articles, coated articles and methods of coating such articles with a rare earth metal containing oxide coating. The coating can contain at least a first metal (e.g., a rare earth metal, tantalum, zirconium, etc.) and a second metal that have been co-deposited onto a surface of the article. The coating can include a homogenous mixture of the first metal and the second metal and does not contain mechanical segregation between layers in the coating.

Abstract: An electronic device manufacturing system includes a mass flow controller (MFC) that has a thermal flow sensor. The thermal flow sensor may measure a mass flow rate and may include a sensor tube having an inner surface coated with a material to form an inner barrier layer. The inner barrier layer may prevent or substantially reduce the likelihood of a corrosive reaction from occurring on the inner surface, which may prevent or reduce the likelihood of the MFC drifting beyond the MFC's mass flow rate accuracy specifications. This may improve the repeatability of flow detection by the MFC. Methods of measuring and controlling a mass flow rate in an electronic device manufacturing system are also provided, as are other aspects.

Abstract: Disclosed are rare earth metal containing silicate coatings, coated articles (e.g., heaters and susceptors) or bodies of articles and methods of coating such articles with a rare earth metal containing silicate coating.

Abstract: Disclosed herein is a rare-earth oxide coating on a surface of an article with one or more interruption layers to control crystal growth and methods of its formation. The coating may be deposited by atomic layer deposition and/or by chemical vapor deposition. The rare-earth oxides in the coatings disclosed herein may have an atomic crystalline phase that is different from the atomic crystalline phase or the amorphous phase of the one or more interruption layers.

Abstract: An enhanced anodization method includes forming a porous anodization layer comprising columns of anodization layer material with pores between adjacent columns. The method further includes sealing the porous layer by forming a sealing layer at a top of the porous layer. The sealing layer may be formed by using a hybrid sealing process that combines, in any order, two or more of de-ionized (DI) water seal, Ni sealing, and, PTFE sealing. Alternatively, the sealing layer is formed by conformally coating the columns in the porous layer with one or more layers of a coating material. Further, the coating material may be surface-fluorinated to improve plasma resistance.

Abstract: An article comprises a body and at least one protective layer on at least one surface of the body. The at least one protective layer is a thin film having a thickness of less than approximately 20 microns that comprises a ceramic selected from a group consisting of Y3Al5O12, Y4Al2O9, Er2O3, Gd2O3, Er3Al5O12, Gd3Al5O12 and a ceramic compound comprising Y4Al2O9 and a solid-solution of Y2O3—ZrO2.

Abstract: Described herein are articles, systems and methods where a halogen resistant coating is deposited onto a surface of a chamber component using an atomic layer deposition (ALD) process. The halogen resistant coating has an optional amorphous seed layer and a transition metal-containing layer. The halogen resistant coating uniformly covers features of the chamber component, such as those having an aspect ratio of about 3:1 to about 300:1.

Abstract: A method for forming a plasma resistant ceramic coating on an article includes placing the article into a chamber or spray cell of a plasma spraying system. A ceramic powder is then fed into the plasma spraying system at a powder feed rate, and a plasma resistant ceramic coating is deposited onto at least one surface of the article in a plasma spray process by the plasma spray system. The plasma spray system is then used to perform an in-situ plasma flame heat treatment of the plasma resistant ceramic coating to form crust on the plasma resistant ceramic coating.

Abstract: Methods for forming a porous coating with a controlled porosity and pore size are described. The methods include mixing a first powder comprising a first material with a second powder comprising a second material to form a mixed powder comprising 30-99 vol. % of the first powder and 1-70 vol. % of the second powder. The methods further include performing cold spray coating to deposit a coating comprising the first material and the second material onto an article, wherein the coating comprises approximately 30-99 vol. % of the first material and 1-70 vol. % of the second material. The methods further include performing a post-coating process to remove the second material from the coating, wherein after the post-coating process the coating consists essentially of the first material and has a porosity that is approximately equivalent to a volume occupied by the second material prior to the post-coating process.

Abstract: Disclosed herein is a rare-earth oxide coating on a surface of an article with one or more interruption layers to control crystal growth and methods of its formation. The coating may be deposited by atomic layer deposition and/or by chemical vapor deposition. The rare-earth oxides in the coatings disclosed herein may have an atomic crystalline phase that is different from the atomic crystalline phase or the amorphous phase of the one or more interruption layers.

Abstract: An article comprises a body having a coating. The coating comprises a Y—O—F coating or other yttrium-based oxy-fluoride coating generated either by performing a fluorination process on a yttrium-based oxide coating or an oxidation process on a yttrium-based fluorine coating.

Abstract: Disclosed herein is a rare-earth oxide coating on a surface of an article with one or more interruption layers to control crystal growth and methods of its formation. The coating may be deposited by atomic layer deposition and/or by chemical vapor deposition. The rare-earth oxides in the coatings disclosed herein may have an atomic crystalline phase that is different from the atomic crystalline phase or the amorphous phase of the one or more interruption layers.

Abstract: An component of a processing chamber comprises an aerosol deposited coating on the component, the aerosol deposited coating comprising a first type of metal oxide nanoparticle and a second type of metal oxide nanoparticle.

Abstract: A chamber component for a processing chamber comprises a ceramic body consisting of a sintered ceramic material consisting essentially of one or more phase of Y2O3—ZrO2. The ceramic material consists essentially of 55-65 mol % Y2O3 and 35-45 mol % ZrO2.

Abstract: An electronic device manufacturing system includes a mass flow controller (MFC) that has a thermal flow sensor. The thermal flow sensor may measure a mass flow rate and may include a sensor tube having an inner surface coated with a material to form an inner barrier layer. The inner barrier layer may prevent or substantially reduce the likelihood of a corrosive reaction from occurring on the inner surface, which may prevent or reduce the likelihood of the MFC drifting beyond the MFC's mass flow rate accuracy specifications. This may improve the repeatability of flow detection by the MFC. Methods of measuring and controlling a mass flow rate in an electronic device manufacturing system are also provided, as are other aspects.

Abstract: A multi-component coating composition for a surface of a semiconductor process chamber component comprising at least one first film layer of a yttrium oxide or a yttrium fluoride coated onto the surface of the semiconductor process chamber component using an atomic layer deposition process and at least one second film layer of an additional oxide or an additional fluoride coated onto the surface of the semiconductor process chamber component using an atomic layer deposition process, wherein the multi-component coating composition is selected from the group consisting of YOxFy, YxAlyO, YxZryO and YxZryAlzO.

Abstract: An article comprises a plasma resistant ceramic material comprising Y2O3 at a concentration of approximately 30 molar % to approximately 60 molar %, Er2O3 at a concentration of above 30 molar % to approximately 60 molar %, and at least one of ZrO2, Gd2O3 or SiO2 at a concentration of over 0 molar % to approximately 30 molar %.