An ion beam processing apparatus may include a plasma chamber, and a plasma plate, disposed alongside the plasma chamber, where the plasma plate defines a first extraction aperture. The apparatus may include a beam blocker, disposed within the plasma chamber and facing the extraction aperture. The apparatus may further include a non-planar electrode, disposed adjacent the beam blocker and outside of the plasma chamber; and an extraction plate, disposed outside the plasma plate, and defining a second extraction aperture, aligned with the first extraction aperture.

A system includes an electrode. The electrode includes a showerhead having a first stem portion and a head portion. A plurality of dielectric layers is vertically stacked between the electrode and a first surface of a conducting structure. The plurality of dielectric layers includes M dielectric layers arranged adjacent to the head portion and P dielectric portions arranged around the first stem portion. The plurality of dielectric layers defines a first gap between the electrode and one of the plurality of dielectric layers, a second gap between adjacent ones of the plurality of dielectric layers, and a third gap between a last one of the plurality of dielectric layers and the first surface. A number of the plurality of dielectric layers and sizes of the first gap, the second gap, and the third gap are selected to prevent parasitic plasma between the first surface and the electrode.

An electrostatic chuck of an embodiment includes a base, a dielectric layer, and a chuck main body. The dielectric layer is provided on the base, and is fixed to the base. The chuck main body is mounted on the dielectric layer. The chuck main body has a ceramic main body, a first electrode, a second electrode, and a third electrode. The ceramic main body has a substrate mounting region. The first electrode is provided in the substrate mounting region. The second electrode and the third electrode form a bipolar electrode. The second electrode and the third electrode are provided in the ceramic main body, and are provided between the first electrode and the dielectric layer.

A switch device of an embodiment includes a first electrode including a first layer including at least one selected from the group consisting of B, C, Al, Si, and Ga, a second electrode separated from the first electrode, a first grid disposed between the first electrode and the second electrode, and a second grid disposed between the first grid and the second electrode.

A stage includes an electrostatic chuck that supports a substrate and an edge ring; and a base that supports the electrostatic chuck. The electrostatic chuck includes a first region having a first upper surface and supports the substrate placed on the first upper surface; a second region having a second upper surface, provided integrally around the first region, and supports the edge ring placed on the second upper surface; a first electrode provided in the first region to apply a DC voltage; a second electrode provided in the second region to apply a DC voltage, and a third electrode to apply a bias power.

Plasma source assemblies comprising an RF hot electrode having a body and at least one return electrode spaced from the RF hot electrode to provide a gap in which a plasma can be formed. An RF feed is connected to the RF hot electrode at a distance from the inner peripheral end of the RF hot electrode that is less than or equal to about 25% of the length of the RF hot electrode. The RF hot electrode can include a leg and optional triangular portion near the leg that extends at an angle to the body of the RF hot electrode. A cladding material on one or more of the RF hot electrode and the return electrode can be variably spaced or have variable properties along the length of the plasma gap.

Provided is a protective material ring in which a plurality of silicon members are joined. A protective material ring is to be installed in a treatment chamber of a substrate treatment apparatus performing plasma treatment on a substrate, and the substrate is accommodated in the treatment chamber. The protective material ring includes: three or more silicon members; and a joining part joining the silicon members. The joining part contains boron oxide.

A substrate support for use in a plasma processing chamber includes a substrate support body, a lifter pin and a lift mechanism. The substrate support body has a pin through-hole and the pin through-hole has a female-threaded inner wall. The lifter pin has a base segment, an intermediate segment, and a leading segment. The lifter pin is inserted into the pin through-hole, the intermediate segment is male-threaded, and the male-threaded intermediate segment is screwable to the female-threaded inner wall. The lift mechanism is configured to vertically move the lifter pin relative to the substrate support body.

An electrostatic chuck of an embodiment includes a base, a dielectric layer, and a chuck main body. The dielectric layer is provided on the base, and is fixed to the base. The chuck main body is mounted on the dielectric layer. The chuck main body has a ceramic main body, a first electrode, a second electrode, and a third electrode. The ceramic main body has a substrate mounting region. The first electrode is provided in the substrate mounting region. The second electrode and the third electrode form a bipolar electrode. The second electrode and the third electrode are provided in the ceramic main body, and are provided between the first electrode and the dielectric layer.

Embodiments described herein generally relate to plasma assisted or plasma enhanced processing chambers. More specifically, embodiments herein relate to electrostatic chucking (ESC) substrate supports configured to provide pulsed DC voltage to a substrate, and methods of biasing the substrate using the pulsed DC voltage, during plasma assisted or plasma enhanced semiconductor manufacturing processes.