According to one embodiment, an electrostatic chuck includes a ceramic dielectric substrate, a base plate, and first and second electrode layers. The ceramic dielectric substrate includes first and second major surfaces. The first and second electrode layers are provided inside the ceramic dielectric substrate. The second electrode layer is provided between the first electrode layer and the first major surface. The first electrode layer includes first and second portions. The first portion is positioned more centrally of the ceramic dielectric substrate than is the second portion. The first portion includes first and second surfaces. The second portion includes third and fourth surfaces. The third surface is positioned between the first surface and the second electrode layer. An electrical resistance of the first surface is greater than an average electrical resistance of the first portion.

A substrate alignment device includes first and second support members that are arranged to be opposite to each other and be spaced apart from each other in a plan view, and respectively support an outer peripheral end of a substrate from a position below the substrate. Further, the substrate alignment device includes a first pressing member that is arranged to be opposite to the first support member in a plan view, and moves the substrate by pressing one portion of the outer peripheral end of the substrate in a first direction directed from the second support member toward the first support member with the substrate supported by the first and second support members. The first support member includes a movement limiter that limits movement of the substrate in the first direction past a predetermined prescribed position.

A substrate bonding apparatus includes a substrate susceptor to support a first substrate, a substrate holder over the substrate susceptor to hold a second substrate, the substrate holder including a plurality of independently moveable holding fingers, and a chamber housing to accommodate the substrate susceptor and the substrate holder.

Disclosed is a plasma processing device that provides an object to be treated with plasma treatment. A wafer as an object to be treated, which is attached on the upper surface of adhesive sheet held by a holder frame, is mounted on a stage. In a vacuum chamber that covers the stage therein, plasma is generated, by which the wafer mounted on the stage undergoes plasma treatment. The plasma processing device contains a cover member made of dielectric material. During the plasma treatment on the wafer, the holder frame is covered with a cover member placed at a predetermined position above the stage, at the same time, the wafer is exposed from an opening formed in the center of the cover member.

An electrostatic chuck device includes: an electrostatic chuck plate having a dielectric substrate having a placement surface on which a wafer is placed and an adsorption electrode positioned in the dielectric substrate; a metal base supporting the electrostatic chuck plate from a back surface side opposite to the placement surface; and a focus ring installed on an outer peripheral portion of the electrostatic chuck plate and surrounding the placement surface. The electrostatic chuck plate has a ring adsorption region which is adsorbed to the focus ring and is located on a surface positioned on the same side as the placement surface and has a base adsorption region which is adsorbed to the metal base and located on a back surface opposite to the placement surface.

A substrate processing system includes a vacuum transfer module; a plasma process module; a transfer robot in the vacuum transfer module; a stage in the plasma process module; a first ring disposed on the stage and a second ring disposed on the first ring to surround a substrate that is placed on the stage, the second ring having an inner diameter smaller than an inner diameter of the first ring; actuators to move support pins vertically to raise the first and the second rings and a transfer jig; and a controller configured to selectively execute a simultaneous transfer mode in which the transfer robot is caused to simultaneously transfer the first ring and the second ring and a sole transfer mode in which the transfer robot is caused to transfer only the second ring.

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.

Provided is a substrate support unit including an electrostatic chuck configured to fix a wafer, an insulating isolation unit, which is arranged below the electrostatic chuck and is configured to insulate the electrostatic chuck, and a ground plate arranged below the insulating isolation unit, wherein the electrostatic chuck, the insulating isolation unit, and the ground plate are spaced apart from each other in a vertical direction, and a lower surface of the electrostatic chuck, a surface of the insulating isolation unit, or a surface of the ground plate has hydrophobicity.

Embodiments of substrate supports are provided herein. In some embodiments, a substrate support for use in a substrate processing chamber includes a ceramic plate having a first side configured to support a substrate and a second side opposite the first side, wherein the ceramic plate includes an electrode embedded in the ceramic plate; a ceramic ring disposed about the ceramic plate and having a first side and a second side opposite the first side, wherein the ceramic ring includes a chucking electrode and a heating element embedded in the ceramic ring; and a cooling plate coupled to the second side of the ceramic plate and the second side of the ceramic ring, wherein the cooling plate includes a radially inner portion, a radially outer portion, and a thermal break disposed therebetween.

A substrate support device relating to technology disclosed in the description of the present application includes: a holding plate for opposing a substrate bowable by being heated by irradiation with flash light; and a plurality of substrate support pins provided on the holding plate and being for supporting the substrate, wherein the plurality of substrate support pins are arranged at locations where a volume of a space between the holding plate and the substrate in an unbowed state and a volume of a space between the holding plate and the substrate in a bowed state are equal to each other. Breakage of the substrate can be suppressed in a case where the substrate is bowed by flash light.