A consumable part and methods for tracking the consumable part includes embedding a radio frequency tag within a pocket created on a side of the consumable part that faces away from a process region defined within a process chamber of the processing tool and covering an opening of the pocket using a plug. The plug is laser fused along an interface formed between sidewalls of the plug and sidewalls of the pocket.

Implementations of the present disclosure provide a process kit for an electrostatic chuck. In one implementation, a substrate support assembly is provided. The substrate support assembly includes an electrostatic chuck having a first recess formed in an upper portion of the electrostatic chuck. A process kit surrounds the electrostatic chuck. The process kit includes an inner ring and an outer ring disposed radially outward of the inner ring. The outer ring includes a second recess formed in an upper portion of the upper ring. The inner ring is positioned within and is supported by the first recess and the second recess. An upper surface of the inner ring and an upper surface of the outer ring are co-planar.

A substrate processing system installed on a floor face is provided. The substrate processing system includes a substrate transfer module, a supporting table including a top plate disposed separately from the floor face, a plurality of substrate processing modules disposed on the top plate and coupled to the substrate transfer module along a lateral side of the substrate transfer module, and a plurality of power units disposed below the top plate. Further, the plurality of power units correspond to the plurality of substrate processing modules, respectively, and each of the power units is configured to supply electric power to the corresponding processing module.

A substrate processing system includes a vacuum transfer module and a plurality of process modules defining respective processing chambers. The plurality of process modules includes a first row of the process modules arranged on a first side of the vacuum transfer module and a second row of the process modules arranged on a second side of the vacuum transfer module opposite the first side. Each of the plurality of process modules includes a gas box arranged above the process module and configured to selectively supply at least one gas and/or gas mixture into the processing chamber of the process module and a radio frequency (RF) generator configured to generate RF power to create plasma within the processing chamber. The RF generator is arranged above the process module and the gas box and the RF generator are arranged side-by-side above the process module.

A plasma source ion implanter with a preparation chamber for linear or cross transferring workpiece is provided to solve the problem of low production efficiency of an existing single vacuum chamber plasma source ion implanter. The ion implanter includes a preparation chamber, an implantation chamber and a workpiece transferring chamber. The implantation chamber is provided to maintain a high vacuum condition all the time, and the time for pre-vacuuming the base vacuum is ignored. The ion implanter with dual chamber configuration is able to greatly shorten the production cycle. The structural configurations of the preparation chamber and the implantation chamber are basically the same, and are adapted to be used independently when ion implantation is required for a long time.

A plasma processing apparatus, to which process control such as APC is applied, includes: a processing chamber in which plasma processing is performed on a sample; and a plasma processing control device which performs control to optimize a condition for plasma processing which recovers the status inside a processing chamber, in which plasma processing is performed, based on a waiting time from the time when plasma processing for a second lot, which is a lot immediately before a first lot, is completed to the time when plasma processing for the first lot is started, and the content of plasma processing for the second lot.

A transfer chamber for a processing system suitable for processing a plurality of substrates and a method of using the same is provided. The transfer chamber includes a lid, a bottom disposed opposite the lid, a plurality of sidewalls sealingly coupling the lid to the bottom and defining an internal volume, wherein the plurality of sidewalls form the faces of a dodecagon. An opening is formed in each of the faces, wherein the opening is configured for a substrate to pass therethrough. A transfer robot is disposed in the internal volume, wherein the transfer robot has effectors configured to support the substrate through one opening to another opening.

A plasma processing apparatus includes: a detector configured to detect a change in an intensity of light emission from plasma formed inside a processing chamber; and a unit configured to adjust conditions for forming the plasma or processing a wafer arranged inside the processing chamber using an output from the detector, wherein the detector detects a signal of the intensity of light emission at plural time instants before an arbitrary time instant during processing, and wherein the adjusting unit removes the component of a temporal change of a long cycle of the intensity of light emission from this detected signal and detects the component of a short temporal change of the intensity of light emission, and adjusts the conditions for forming the plasma or processing a wafer arranged inside the processing chamber based on the short temporal change of the detected intensity of light emission.

A placing table on an embodiment includes a supporting member and a base. The supporting member includes a placing region provided with a heater, and an outer peripheral region surrounding the placing region. The base includes a first region supporting the placing region thereon, and a second region surrounding the first region. In the second region, through holes are formed. Wirings electrically connected to the heater passes through the through holes of the second region.

Disclosed are systems, methods, and devices for generating radicals in an air stream at the intake of an internal combustion engine, as well as increasing the thrust of such air streams into the engine. A plasma generator including plasma actuators, dielectric barrier discharge electrodes, or both is positioned in the intake stream. Plasma actuators are disposed on the interior surface of the plasma generator, exposed to the intake stream. Dielectric barrier discharge electrodes protrude into the intake air stream. Plasma, preferably DBD plasma, glow plasma, or filamentary plasma, is generated in the air intake stream, creating radicals in the stream, mixing the radicals in the stream, and reducing drag while increasing thrust of air in the intake stream. A concentric cylinder can be further disposed in the plasma generator, with further plasma actuators, dielectric barrier discharge electrodes, or both, on the interior and exterior surfaces of the cylinder.