Abstract: Implementations of the present disclosure generally relate to an improved substrate support pedestal assembly. In one implementation, the substrate support pedestal assembly includes a shaft. The substrate support pedestal assembly further includes a substrate support pedestal, mechanically coupled to the shaft. The substrate support pedestal comprises substrate support plate coated on a top surface with a ceramic material.

Abstract: A substrate support for supporting a substrate in a substrate processing system includes a baseplate and a ceramic layer arranged above the baseplate. An outer perimeter of the ceramic layer is surrounded by an edge ring. An outer radius of the ceramic layer is greater than an inner radius of the edge ring such that an outer edge of the ceramic layer extends below the edge ring.

Abstract: A substrate supporting plate that may prevent deposition on a rear surface of a substrate and may easily unload the substrate. The substrate supporting plate may include a substrate mounting portion and a peripheral portion surrounding the substrate mounting portion. An edge portion of a top surface of the substrate mounting portion may be anodized. A central portion of the top surface of the substrate mounting portion may not be anodized.

Abstract: A susceptor can include a generally circular shape and may include an inner and outer susceptor. The outer susceptor can include a support region having one or more support mechanisms as well as a channel region extending from the region boundary to an outer radial boundary radially inward of an outer edge of the susceptor, the channel region can include a plurality of channels extending radially from the region boundary to the outer radial boundary. The inner susceptor can include a second plurality of channels extending from the inner radial boundary to an edge of the inner susceptor.

Abstract: Embodiments of substrate supports and process chambers equipped with the same are provided. In some embodiments, a substrate support includes: a support body having a first surface; one or more receptacles extending through the first surface and into the support body; and one or more protrusions respectively disposed within corresponding ones of the one or more receptacles and projecting from the first surface, wherein the one or more protrusions at least partially define a substantially planar support surface above the first surface. Methods of eliminating backside wafer damage are also disclosed.

Abstract: The present disclosure provides a magazine supporting equipment for supporting a magazine with multiple input ports. The magazine supporting equipment comprises a contact plate, a first sidewall plate, and a second sidewall plate. The contact plate is in contact with the magazine. The first sidewall plate extends vertically from one end of the contact plate. The second sidewall plate parallel is to the first sidewall plate and extends vertically from one end to the other end of the contact plate. The first sidewall plate extends along at least a part of a first sidewall of the magazine. The second sidewall plate extends along at least a part of a second sidewall of the magazine. The first sidewall plate and the second sidewall plate include control openings through which gas flows in and out.

Abstract: An electrostatic chuck is described that has radio frequency coupling suitable for use in high power plasma environments. In some examples, the chuck includes a base plate, a top plate, a first electrode in the top plate proximate the top surface of the top plate to electrostatically grip a workpiece, and a second electrode in the top plate spaced apart from the first electrode, the first and second electrodes being coupled to a power supply to electrostatically charge the first electrode.

Abstract: There is provided a technique that includes: a first processing module including a first process container in which at least one substrate is processed, a first utility system including a first supply system which supplies a first processing gas into the first process container and a surface of the first utility system is connected or arranged close to the first processing module; and a first vacuum pump arranged at the same level as a first exhaust port of the first process container. The first vacuum pump exhausts an inside of the first process container and includes a first intake port formed laterally at a position substantially facing the first exhaust port of the first process container. A first exhaust pipe configured to substantially linearly bring the first exhaust port into fluid communication with the first intake port and including a first valve installed in a flow path.

Abstract: Aspects of the present disclosure relate to apparatus, systems, and methods of measuring edge ring distance for thermal processing chambers. In one example, the distance measured is used to determine a center position shift of the edge ring.

Abstract: A support unit provided in an apparatus for treating a substrate using plasma includes a dielectric plate on which the substrate is placed, an electrode plate disposed under the dielectric plate, a power supply rod that applies power to the electrode plate, and a flange that has a shape surrounding the power supply rod and that is spaced apart from the power supply rod.

Abstract: The inventive concept relates to an apparatus and a method for processing a substrate. In an embodiment, the apparatus includes a process chamber having a processing space inside, a support unit that supports the substrate in the processing space, a gas supply unit that supplies a process gas into the processing space, and a plasma source that generates plasma from the process gas. The support unit includes a support on which the substrate is placed, an edge ring around the substrate placed on the support, an impedance adjustment member provided below the edge ring, and a temperature adjustment member that variably adjusts temperature of the impedance adjustment member.

Abstract: Embodiments of a process kit are provided herein. In some embodiments, a process kit for use in a substrate processing chamber includes: a ceramic ring having an upper surface and a lower surface, wherein the ceramic ring includes a chucking electrode disposed in the ceramic ring and a heating element disposed in the ceramic ring; and an edge ring disposed on the ceramic ring.

Abstract: A substrate support includes an electrostatic chuck having an upper surface, and a cover positioned on the electrostatic chuck to cover the upper surface thereof. The cover includes a first face adjacent the upper surface of the electrostatic chuck, a second face for supporting a substrate, and one or more conduits extending through the cover to permit a cooling gas to flow from the second face to the first face. The cover is made from a dielectric material.

Abstract: A substrate retaining apparatus, a load lock assembly comprising the substrate retaining apparatus, and a system including the substrate retaining apparatus are disclosed. The substrate retaining apparatus can include at least one sidewall and one or more heat shields. One or more of the at least one sidewall can include a cooling fluid conduit to facilitate cooling of substrates retained by the substrate retaining apparatus. Additionally or alternatively, one or more of the at least one sidewall can include a gas conduit to provide gas to a surface of a retained substrate.

Abstract: A component comprises a film containing yttrium oxide. A cross section of the film has a first portion, a second portion, and a third portion, and the first to third portions are separated from each other by 0.5 mm or more. A Vickers hardness B1 measured in the first portion, a Vickers hardness B2 measured in the second portion, a Vickers hardness B3 measured in the third portion, and an average value A of the Vickers hardnesses B1 to B3 are numbers satisfying 0.8A?B1?1.2A, 0.8A?B2?1.2A, and 0.8A?B3?1.2A.

Abstract: In a plasma processing apparatus, a mounting table includes a heater for adjusting a temperature of a mounting surface mounting thereon a consumable part consumed by plasma processing. A heater control unit controls a supply power to the heater such that the heater reaches a setting temperature. A measurement unit measures, while controlling the supply power to the heater such that the temperature of the heater becomes constant, the supply powers in a non-ignition state where plasma is not ignited and in a transient state where the supply power is decreased after the plasma is ignited. A parameter calculation unit calculates a thickness of the consumable part by performing fitting with a calculation model, which has the thickness of the consumable part as a parameter and calculates the supply power in the transient state, by using the measured supply powers in the non-ignition state and in the transient state.

Abstract: According to one embodiment, an edge ring is provided which includes a first movable portion provided along an outer circumference of a support portion having an upper surface capable of holding a semiconductor substrate thereon, the first movable portion being movable in a direction perpendicular to the upper surface; a second movable portion provided along an outer circumference of the first movable portion, the second movable portion being movable in the direction; and a driving portion capable of moving the first movable portion in the direction by way of the second movable portion.

Abstract: There is provided a technique that includes abnormality detecting by picking up a sound generated from a transfer configured to be capable of transporting the substrate and comparing a waveform of sound data with a preset threshold value to detect an abnormality of the transfer; and failure detecting by picking up vibration of the transfer and comparing a waveform of vibration data with a preset threshold value to detect a failure of the transfer.

Abstract: According to one embodiment, an electrostatic chuck apparatus includes a substrate support plate formed of a dielectric material. The substrate support plate includes: a plurality of support bases protruding from an upper surface of the substrate support plate, a plurality of ground electrodes formed inside the substrate support plate, each of the ground electrodes at a corresponding position to a respective one the support bases, and an electrostatic chuck electrode provided below the ground electrodes.

Abstract: A semiconductor substrate processing apparatus includes a vacuum chamber having a processing zone in which a semiconductor substrate may be processed, a process gas source in fluid communication with the vacuum chamber for supplying a process gas into the vacuum chamber, a showerhead module through which process gas from the process gas source is supplied to the processing zone of the vacuum chamber, and a substrate pedestal module.