A system includes a transparent crystal, at least part of which is embedded within a wall and a liner of a processing chamber. The transparent crystal has a proximal end and a distal end, the distal end having a distal surface exposed to an interior of the processing chamber. A transparent thin film is deposited on the distal surface and has chemical properties substantially matching those of the liner. A light coupling device is to: transmit light, from a light source, through the proximal end of the transparent crystal, and focus, into a spectrometer, light received reflected back from a combination of the distal surface, a surface of the transparent thin film, and a surface of a process film layer deposited on the transparent thin film. The spectrometer is to detect a first spectrum within the focused light that is representative of the process film layer.

Embodiments disclosed herein include a modular microwave source array. In an embodiment, a housing assembly for the source array comprises a first conductive layer, wherein the first conductive layer comprises a first coefficient of thermal expansion (CTE), and a second conductive layer over the first conductive layer, wherein the second conductive layer comprises a second CTE that is different than the first CTE. In an embodiment, the housing assembly further comprises a plurality of openings through the housing assembly, where each opening passes through the first conductive layer and the second conductive layer.

A plasma processing apparatus includes: a processing container; an electrode that places a substrate thereon within the processing container; a plasma generation source that supplies plasma into the processing container; a bias power supply that supplies bias power to the electrode; a part exposed to the plasma in the processing container; a DC power supply that supplies a DC voltage to the part; a controller that executes a process including a first control procedure in which a first state in which the DC voltage has a first voltage value and a second state in which the DC voltage has a second voltage value higher than the first voltage value are periodically repeated, and the first voltage value is applied in a partial period in each cycle of a potential of the electrode, and the second voltage value is applied such that the first state and the second state are continuous.

A substrate processing apparatus includes a chamber housing with an upper portion opened, the chamber housing defining a reaction space, a susceptor configured to support a substrate in the chamber housing, and a dielectric cover covering an upper portion of the chamber housing. The dielectric cover includes a dielectric lid, and a mode modifying assembly arranged around the dielectric lid to be spaced apart from the dielectric lid, the mode modifying assembly configured to adjust a distance from the dielectric lid.

Embodiments of the present disclosure generally relate to semiconductor processing apparatus. More specifically, embodiments of the disclosure relate to an ICP process chamber. The ICP process chamber includes a chamber body and a lid disposed over the chamber body. The lid is fabricated from a ceramic material. The lid has a monolithic body, and one or more heating elements and one or more coils are embedded in the monolithic body of the lid. The number of components disposed over the lid is reduced with the one or more heating elements and one or more coils embedded in the lid. Furthermore, with the embedded one or more heating elements, the controlling of the thermal characteristics of the lid is improved.

A method for storage and supply of a F3NO-free FNO-containing gas comprises the steps of storing the F3NO-free FNO-containing gas in a NiP coated steel cylinder with a polished inner surface, releasing the F3NO-free FNO-containing gas from the cylinder to a manifold assembly by activating a cylinder valve in fluid communication with the cylinder and the manifold assembly, de-pressurizing the F3NO-free FNO-containing gas by activating a pressure regulator in the manifold assembly so as to divide the manifold assembly into a first pressure zone upstream of the pressure regulator and a second pressure zone downstream of the pressure regulator, and feeding the de-pressurized F3NO-free FNO-containing gas to a target reactor downstream of the second pressure zone.

A plasma-processing apparatus includes a chamber, a plasma generator, and a composite plasma modulator. The chamber includes a plasma zone. The plasma generator is configured to generate a plasma in the plasma zone. The composite plasma modulator is configured to modulate the plasma. The composite plasma modulator includes a dielectric plate made of a first dielectric material and a first modulating portion made of a second dielectric material and coupled to the dielectric plate.

To provide perfluoroelastomer molded product and a protective member, excellent in plasma resistance and fitting property.

A perfluoroelastomer molded product containing no carbon black, and having a shore A hardness of 25 or more and 60 or less, and a protective member comprising the perfluoroelastomer molded product.

Embodiments of process kits for use in a process chamber are provided herein. In some embodiments, a process kit for use in a process chamber includes a slit door having an arcuate profile and including a first plate slidably coupled to a second plate, wherein the first plate is configured to be coupled to an actuator, wherein the second plate has an inner surface that includes silicon, and wherein the inner surface includes a plurality of grooves.

A plasma processing apparatus includes: a processing container; an electrode that places a substrate thereon within the processing container; a plasma generation source that supplies plasma into the processing container; a bias power supply that supplies bias power to the electrode; a part exposed to the plasma in the processing container; a DC power supply that supplies a DC voltage to the part; a controller that executes a process including a first control procedure in which a first state in which the DC voltage has a first voltage value and a second state in which the DC voltage has a second voltage value higher than the first voltage value are periodically repeated, and the first voltage value is applied in a partial period in each cycle of a potential of the electrode, and the second voltage value is applied such that the first state and the second state are continuous.