An ion depth profile control method includes performing reinforcement learning, whereby a similarity between an ion depth profile and a box profile is output as a reward when the similarity is equal to or greater than a set criterion, the ion depth profile being an ion concentration according to a wafer depth in an ion implantation process, and the box profile being a target profile, obtaining at least one process condition of the ion implantation process as a result of the reinforcement learning, and generating a process recipe regarding the at least one process condition.

An ion source with an insertable target holder for holding a solid dopant material is disclosed. The insertable target holder includes a hollow interior into which the solid dopant material is disposed. The target holder has a porous surface at a first end, through which vapors from the solid dopant material may enter the arc chamber. The porous surface inhibits the passage of liquid or molten dopant material into the arc chamber. The target holder is also constructed such that it may be refilled with dopant material when the dopant material within the hollow interior has been consumed. The porous surface may be a portion of a perforated crucible, a portion of a perforated retention cap, or a porous insert.

A thermal chuck selectively retains a workpiece on a clamping surface. The thermal chuck has one or more heaters to selectively heat the clamping surface and the workpiece. A thermal monitoring device determines a temperature of a surface of the workpiece when the workpiece resides on the clamping surface, defining one or more measured temperatures. A controller selectively energizes the one or more heaters based on the one or more measured temperatures. The thermal monitoring device may be one or more of a thermocouple or RTD in selective contact with the surface of the workpiece and an emissivity sensor or pyrometer not in contact with the surface. The thermal chuck can be part of an ion implantation system configured to implant ions into the workpiece. The controller can be further configured to control the heaters based on the measured temperatures.

A bonded wafer including an ion implantation step using a batch processing ion implanter, wherein the ion implantation step is performed by irradiating a bond wafer with a light element ion beam without forming an insulator film on the bond wafer surface or through an insulator film having a thickness of 50 nm or less formed on the bond wafer surface at an implantation angle inclined from a crystal axis of the bond wafer; and the bond wafer surface is irradiated with the center of the light element ion beam shining at a position on the bond wafer surface shifted from the center of the bond wafer parallel to the center of a rotor by a predetermined amount providing a bonded wafer to prevent degradation of the radial uniformity of ion implantation depth and manufacture a bonded wafer with excellent radial uniformity of thickness of a thin film after delamination.

A first edge ring for a substrate support is provided. The first edge ring includes an annular-shaped body and one or more lift pin receiving elements. The annular-shaped body is sized and shaped to surround an upper portion of the substrate support. The annular-shaped body defines an upper surface, a lower surface, a radially inner surface, and a radially outer surface. The one or more lift pin receiving elements are disposed along the lower surface of the annular-shaped body and sized and shaped to receive and provide kinematic coupling with top ends respectively of three or more lift pins.

A method includes depositing a second dielectric layer over a first dielectric layer, depositing a third dielectric layer over the second dielectric layer, patterning a plurality of first openings in the third dielectric layer, etching the second dielectric layer through the first openings to form second openings in the second dielectric layer, performing a plasma etching process directed at the second dielectric layer from a first direction, the plasma etching process extending the second openings in the first direction, and etching the first dielectric layer through the second openings to form third openings in the first dielectric layer.

An ion beam treatment or implantation system includes an ion source emitting ion beams. The ion source includes a microwave source and a curved waveguide conduit having openings therein. The waveguide conduit is coupled to the microwave source for transmitting microwaves from the microwave source through the plurality of openings. The ion source also includes a curved plasma chamber in communication with the waveguide conduit through the openings. The plasma chamber receives through the openings microwaves from the waveguide conduit. The plasma chamber includes magnets disposed in an outer wall of the plasma chamber for forming a magnetic field in the plasma chamber. The plasma chamber further includes a charged cover at a side of the chamber opposite the side containing the openings. The cover includes extraction holes through which the ion beams are extracted.

An ion beam treatment or implantation system includes an ion source emitting a plurality of parallel ion beams having a given spacing. A first lens magnet having a non-uniform magnetic field receives the plurality of ion beams from the ion source and focuses the plurality of ion beams toward a common point. The system may optionally include a second lens magnet having a non-uniform magnetic field receiving the ion beams focused by the first lens magnet and redirecting the ion beams such that they have a parallel arrangement having a closer spacing than said given spacing in a direction toward a target substrate.

A measurement device includes a plurality of slits, a beam current measurement unit provided at a position away from the slits in a beam traveling direction, and a measurement control unit. The beam current measurement unit is configured to be capable of measuring a beam current at a plurality of measurement positions to be different positions in a first direction perpendicular to the beam traveling direction. The slits are disposed to be spaced apart in the first direction such that the first direction coincides with a slit width direction and are configured to be movable in the first direction. The measurement control unit acquires a plurality of beam current values measured at the plurality of measurement positions to be the different positions in the first direction with the beam current measurement unit while moving the slits in the first direction.

A method for treating a silicon substrate, and a silicon substrate, provide a surface treated with an accelerated neutral beam.