Proposed are a part having a corrosion-resistant layer that minimizes peeling off and particle generation of a porous ceramic layer, a manufacturing process apparatus having the same, and a method of manufacturing the part.

Articles may be protected against halide plasma, by applying a rare earth-containing glaze to the surface of the article. The glaze may be a coating comprising; 20 to 90 mol % SiO.sub.2, 0 to 60 mol % Al.sub.2O.sub.3, 10 to 80 mol % rare earth oxides and/or rare earth fluorides (REX), wherein SiO.sub.2+Al.sub.2O.sub.3+REX≥60 mol %.

Disclosed in some embodiments is a chamber component (such as an end effector body) coated with an ultrathin electrically-dissipative material to provide a dissipative path from the coating to the ground. The coating may be deposited via a chemical precursor deposition to provide a uniform, conformal, and porosity free coating in a cost effective manner. In an embodiment wherein the chamber component comprises an end effector body, the end effector body may further comprise replaceable contact pads for supporting a substrate and the contact surface of the contact pads head may also be coated with an electrically-dissipative material.

Thermally isolated captive features disposed in various components of an ion implantation system are disclosed. Electrodes, such as repellers and side electrodes, may be constructed with a captive feature, which serves as the electrode stem. The electrode stem makes minimal physical contact with the electrode mass due to a gap disposed in the interior cavity which retains the flared head of the electrode stem. In this way, the temperature of the electrode mass may remain higher than would otherwise be possible as conduction is reduced. Further, this concept can be applied to workpiece holders. For example, a ceramic platen is manufactured with one or more captive fasteners which are used to affix the platen to a base. This may minimize the thermal conduction between the platen and the base, while providing an improved mechanical connection.

A first lift pin holder assembly includes a base portion and a stem portion including a ball lock mechanism to hold a lift pin. A second lift pin holder assembly includes a base portion and a stem portion including a fork lock mechanism to hold a lift pin. A slotted ring with coin-slot type slots is arranged on abase of a substrate support assembly. A plurality of the first or second lift pin holder assemblies are retained in the slots using retainers that surround the base portions of the lift pin holder assemblies. Each slot includes an aperture in which a T-shaped retainer is inserted. The top portion of the T-shaped retainer prevents the retainer and the lift pin holder assembly from sliding out of the slot. The lift pin, the lift pin holder assemblies, the retainers, the T-shaped retainer, and the slotted ring are made of ceramic materials.

Embodiments of substrate supports for use in microwave degas chambers are provided herein. In some embodiments, a substrate support for use in a microwave degas chamber includes a support plate having one or more support features for supporting a substrate; a susceptor comprising a plate disposed on the support plate, wherein the susceptor includes one or more openings, wherein the one or more support features extend through corresponding ones of the one or more openings; and a metal foil disposed beneath a side of the susceptor facing the support plate.

A substrate processing apparatus includes a processing vessel; a placing table provided within the processing vessel and configured to place a substrate thereon; and a component disposed between the processing vessel and the placing table, the component constituting an anode. The component has a flow path through which a heat exchange medium flows.

Semiconductor processing apparatuses and methods are provided in which an electrostatic discharge (ESD) prevention layer is utilized to prevent or reduce ESD events from occurring between a semiconductor wafer and one or more components of the apparatuses. In some embodiments, a semiconductor processing apparatus includes a wafer handling structure that is configured to support a semiconductor wafer during processing of the semiconductor wafer. The apparatus further includes an ESD prevention layer on the wafer handling structure. The ESD prevention layer includes a first material and a second material, and the second material has an electrical conductivity that is greater than an electrical conductivity of the first material.

A member for a semiconductor manufacturing apparatus includes a disk-shaped or annular ceramic heater, a metal base, an adhesive element bonding the metal base and the ceramic heater, an adhesive protective element disposed between the ceramic heater and the metal base to extend along a periphery of the adhesive element, and an anti-adhesion layer disposed between the adhesive element and the protective element, the anti-adhesion layer preventing adhesion between the adhesive element and the protective element.

A wafer placement table includes a ceramic substrate that has a wafer placement surface, a first electrode that is embedded in the ceramic substrate, a first power supply terminal that is inserted from a surface of the ceramic substrate opposite the wafer placement surface toward the first electrode, a first joint that joins the first electrode and the first power supply terminal to each other and a second electrode that is disposed between the wafer placement surface and the first electrode in the ceramic substrate. A linear portion that extends in the ceramic substrate from a position on the first electrode opposite the first joint to the wafer placement surface is composed of material of the ceramic substrate.