Abstract: A method, including using an implant recipe to perform an implant by scanning an ion beam along a first axis over a substrate, coated with a photoresist layer, while the substrate is scanned along a perpendicular axis; measuring an implant current (I) during the implant, using a first detector, positioned to a side of a substrate position; determining a value of a difference ratio (I?B)/(B), based upon the implant current, where B is current measured by the first detector, during a calibration at base pressure; determining a plurality of values of a current ratio (CR) for the plurality of instances, based upon the difference ratio, the current ratio being a ratio of the implant current to a current measured by a second detector, positioned over the substrate position, during the calibration; and adjusting scanning the ion beam, scanning of the substrate, or a combination thereof, based upon the current ratio.

Abstract: A method, including using an implant recipe to perform an implant by scanning an ion beam along a first axis over a substrate, coated with a photoresist layer, while the substrate is scanned along a perpendicular axis; measuring an implant current (I) during the implant, using a first detector, positioned to a side of a substrate position; determining a value of a difference ratio (I?B)/(B), based upon the implant current, where B is current measured by the first detector, during a calibration at base pressure; determining a plurality of values of a current ratio (CR) for the plurality of instances, based upon the difference ratio, the current ratio being a ratio of the implant current to a current measured by a second detector, positioned over the substrate position, during the calibration; and adjusting scanning the ion beam, scanning of the substrate, or a combination thereof, based upon the current ratio.

Abstract: A mask or set of masks is disclosed in which outward projections are placed on either side of at least one aperture. An ion beam is then directed through the mask toward a workpiece. An ion collecting device or an optical system is then used to measure the alignment of the mask to the ion beam. These projections serve to increase the sensitivity of the system to misalignment. In another embodiment, a blocker is used to create a region of the workpiece that is not subjected to a blanket implant. This facilitates the use of optical means to insure and determine alignment of the mask to the ion beam.

Abstract: A charge monitoring system may include a platen having a surface configured to accept a wafer thereon, and a charge monitor disposed relative to the platen so that an ion beam simultaneously strikes a portion of the charge monitor and a portion of the wafer. The charge monitor is configured to provide a charge monitor signal representative of a charge on a surface of the wafer when the ion beam simultaneously strikes the portion of the charge monitor and the portion of the wafer. The charge monitor signal may depend, at least in part, on a beam potential of the ion beam.

Abstract: Systems and methods that neutralize ion beams in implantation processes are provided. The methods involve introducing a gas into the ion beam. The gas, for example, can be introduced into a region defined by an electrode through which the ion beam travels. The gas increases the generation of electrons in the beam which, in turn, neutralizes the beam. The neutralized beam has a reduced tendency to diverge (i.e., greater beam stability) during transport which can increase the beam current delivered to the wafer and implant uniformity, amongst other advantages. The systems and methods are particularly useful in limiting the divergence of low energy ion beams.

Abstract: A Faraday system for measuring ion beam current in an ion implanter or other ion beam treatment system includes a Faraday cup body defining a chamber which has an entrance aperture for receiving an ion beam, a suppression electrode positioned in proximity to the entrance aperture to produce electric fields for inhibiting escape of electrons from the chamber, and a magnet assembly positioned to produce magnetic fields for inhibiting escape of electrons from the chamber. The chamber may have a relatively small ratio of chamber depth to entrance aperture width.

Abstract: Systems and methods that neutralize ion beams in implantation processes are provided. The methods involve introducing a gas into the ion beam. The gas, for example, can be introduced into a region defined by an electrode through which the ion beam travels. The gas increases the generation of electrons in the beam which, in turn, neutralizes the beam. The neutralized beam has a reduced tendency to diverge (i.e., greater beam stability) during transport which can increase the beam current delivered to the wafer and implant uniformity, amongst other advantages. The systems and methods are particularly useful in limiting the divergence of low energy ion beams.

Abstract: A Faraday system for measuring ion beam current in an ion implanter or other ion beam treatment system includes a Faraday cup body defining a chamber which has an entrance aperture for receiving an ion beam, a suppression electrode positioned in proximity to the entrance aperture to produce electric fields for inhibiting escape of electrons from the chamber, and a magnet assembly positioned to produce magnetic fields for inhibiting escape of electrons from the chamber. The chamber may have a relatively small ratio of chamber depth to entrance aperture width.