A bevel mask for use in plasma CVD apparatus for depositing a more uniform film while preventing film peeling at the edges of the wafer. The bevel mask includes a bulk portion and an edge portion. The bulk portion includes an inner beveled surface or face, and the edge portion extends outward from a bottom section of the inner beveled surface to provide a covering for a peripheral portion of the upper surface of a wafer received on the susceptor, which supports the annular-shaped mask such as upon a ring structure on an upper surface of the susceptor.

A wafer placement table includes a ceramic base having a wafer placement surface on its top surface where a wafer is able to be placed and incorporating an electrode, a cooling base bonded to a bottom surface of the ceramic base and having a refrigerant flow channel, a plurality of holes extending through the cooling base in an up and down direction, and a heat exchange promoting portion that is provided in an area around at least one of the plurality of holes and that promotes heat exchange between refrigerant flowing through the refrigerant flow channel and a wafer placed on the wafer placement surface.

An electrostatic chuck for electrostatically attracting a substrate includes: a chuck body formed of first ceramic particles and having a substrate-facing surface facing the substrate attracted to the electrostatic chuck; and a plurality of convex portions formed on the substrate-facing surface of the chuck body, wherein each of the plurality of convex portions excluding at least a tip-side layer is formed of second ceramic particles having a major axis diameter of 20 μm or more and 2,000 μm or less and has a porosity of 0.1% or more and 1.0% or less.

The present disclosure discloses a semiconductor processing apparatus, which is configured to perform processing on a wafer. The disclosed semiconductor processing apparatus includes a vacuum interlock chamber, a plurality of apparatus bodies, the apparatus body including a transfer platform, and at least two reaction chambers being arranged along a circumferential direction of the transfer platform, and a temporary storage channel, any two neighboring apparatus bodies being communicated through the temporary storage channel, and the temporary storage channel being configured to temporarily store the wafer. One of the plurality apparatus bodies is connected to the vacuum interlock chamber. The transfer platform is configured to transfer the wafer between the vacuum interlock chamber and the reaction chamber, between the temporary storage channel and the vacuum interlock chamber, and between the temporary storage channel and the reaction chamber. With the above solution, the problem that the productivity of the semiconductor processing apparatus is low is solved.

Described herein is a protective coating composition that provides erosion and corrosion resistance to a coated article (such as a chamber component) upon the article's exposure to harsh chemical environment (such as hydrogen based and/or halogen based environment) and/or upon the article's exposure to high energy plasma. Also described herein is a method of coating an article with the protective coating using electronic beam ion assisted deposition, physical vapor deposition, or plasma spray. Also described herein is a method of processing wafer, which method exhibits, on average, less than about 5 yttrium based particle defects per wafer.

A substrate processing apparatus includes a substrate holding section, a chemical liquid supply section, a substrate information acquiring section, a chemical liquid processing condition information acquiring section, and a controller. The substrate information acquiring section acquires substrate information including hardened layer thickness information indicating a thickness of a hardened layer in a resist layer of a processing target substrate or ion implantation condition information indicating a condition for ion implantation by which the hardened layer has been formed in the resist layer. The chemical liquid processing condition information acquiring section acquires based on the substrate information chemical liquid processing condition information indicating a chemical liquid processing condition for the processing target substrate from a trained model. The controller controls the substrate holding section and the chemical liquid supply section -to perform processing with a chemical liquid on the processing target substrate based on the chemical liquid processing condition information.

A novel deposition method of a metal oxide is provided. The deposition method includes a first step of supplying a first precursor to a chamber; a second step of supplying a second precursor to the chamber; a third step of supplying a third precursor to the chamber; and a fourth step of introducing an oxidizer into the chamber after the first step, the second step, and the third step. The first to third precursors are different kinds of precursors, and a substrate placed in the chamber in the first to fourth steps is heated to a temperature higher than or equal to 300° C. and lower than or equal to decomposition temperatures of the first to third precursors.

A deposition system is provided capable of measuring at least one of the film characteristics (e.g., thickness, resistance, and composition) in the deposition system. The deposition system in accordance with the present disclosure includes a substrate process chamber. The deposition system in accordance with the present disclosure includes a substrate pedestal in the substrate process chamber, the substrate pedestal configured to support a substrate, and a target enclosing the substrate process chamber. A shutter disk including an in-situ measuring device is provided.

Provided is a dry etching apparatus including: a plasma process chamber; an edge ring which is arranged in the plasma process chamber and on which a wafer is mounted; a shadow ring positioned to be spaced apart by a first vertical distance above the edge ring during a plasma etching process of the wafer; an operation unit coupled to the shadow ring and having a lift pin that raises and lowers the shadow ring; a fixing portion having a plurality of fixing pins engaged with the lift pin at different positions to fix a lowering point of the shadow ring; and a distance control unit that controls the fixing portion to determine the first vertical distance, wherein the first vertical distance is determined by a first horizontal distance between the wafer and the edge ring.

Contamination from outgassing during a deposition process is addressed by a series of equipment enhancements, including throttle valves, a dual air curtain, and a residual gas analysis (RGA) monitor. The dual air curtain can be configured to flow a first gas during wafer processing and a second gas during wafer unloading, to re-direct and capture outgassed species. The dual air curtain and the throttle valves can be programmed in an automated feedback control system that utilizes data from the RGA monitor.