Abstract: A scanning magnet is positioned downstream of a mass resolving magnet of an ion implantation system and is configured to control a path of an ion beam downstream of the mass resolving magnet for a scanning or dithering of the ion beam. The scanning magnet has a yoke having a channel defined therein. The yoke is ferrous and has a first side and a second side defining a respective entrance and exit of the ion beam. The yoke has a plurality of laminations stacked from the first side to the second side, wherein at least a portion of the plurality of laminations associated with the first side and second side comprise one or more slotted laminations having plurality of slots defined therein.

Abstract: An ion implantation system and method provide a non-uniform flux of a ribbon ion beam. A spot ion beam is formed and provided to a scanner, and a scan waveform having a time-varying potential is applied to the scanner. The ion beam is scanned by the scanner across a scan path, generally defining a scanned ion beam comprised of a plurality of beamlets. The scanned beam is then passed through a corrector apparatus. The corrector apparatus is configured to direct the scanned ion beam toward a workpiece at a generally constant angle of incidence across the workpiece. The corrector apparatus further comprises a plurality of magnetic poles configured to provide a non-uniform flux profile of the scanned ion beam at the workpiece.

Abstract: An ion implantation system and method provide a non-uniform flux of a ribbon ion beam. A spot ion beam is formed and provided to a scanner, and a scan waveform having a time-varying potential is applied to the scanner. The ion beam is scanned by the scanner across a scan path, generally defining a scanned ion beam comprised of a plurality of beamlets. The scanned beam is then passed through a corrector apparatus. The corrector apparatus is configured to direct the scanned ion beam toward a workpiece at a generally constant angle of incidence across the workpiece. The corrector apparatus further comprises a plurality of magnetic poles configured to provide a non-uniform flux profile of the scanned ion beam at the workpiece.

Abstract: A scanning magnet is positioned downstream of a mass resolving magnet of an ion implantation system and is configured to control a path of an ion beam downstream of the mass resolving magnet for a scanning or dithering of the ion beam. The scanning magnet has a yoke having a channel defined therein. The yoke is ferrous and has a first side and a second side defining a respective entrance and exit of the ion beam. The yoke has a plurality of laminations stacked from the first side to the second side, wherein at least a portion of the plurality of laminations associated with the first side and second side comprise one or more slotted laminations having plurality of slots defined therein.

Abstract: An electrode system for an ion source has a source electrode that defines a source aperture in an ion source chamber, and is coupled to a source power supply. A first ground electrode defines a first ground aperture that is electrically coupled to an electrical ground potential and extracts ions from the ion source. A suppression electrode is positioned downstream of the first ground electrode and defines a suppression aperture that is electrically coupled to a suppression power supply. A second ground electrode is positioned downstream of the suppression electrode and defines a second ground aperture. The first and second ground electrodes are fixedly coupled to one another and are electrically coupled to the electrical ground potential.

Abstract: An ion implantation system and method provide a non-uniform flux of a ribbon ion beam. A spot ion beam is formed and provided to a scanner, and a scan waveform having a time-varying potential is applied to the scanner. The ion beam is scanned by the scanner across a scan path, generally defining a scanned ion beam comprised of a plurality of beamlets. The scanned beam is then passed through a corrector apparatus. The corrector apparatus is configured to direct the scanned ion beam toward a workpiece at a generally constant angle of incidence across the workpiece. The corrector apparatus further comprises a plurality of magnetic poles configured to provide a non-uniform flux profile of the scanned ion beam at the workpiece.

Abstract: A modular ion source and extraction apparatus comprises an ion source chamber selectively electrically coupled to a voltage potential, wherein the ion source chamber comprises an extraction aperture. An extraction electrode is positioned proximate to the extraction aperture of the ion source chamber, wherein the extraction electrode is electrically grounded and configured to extract ions from the ion source chamber. One or more linkages operably couple to the ion source chamber, and one or more insulators couple the extraction electrode to the respective one or more linkages, wherein the one or more insulators electrically insulate the respective one or more linkages from the extraction electrode, therein electrically insulating the extraction electrode from the ion source chamber.

Abstract: A method and apparatus is provided for generating a plasma electron flood using microwave radiation. In one embodiment, a microwave PEF apparatus is configured to generate a magnetic field that rapidly decays over a PEF cavity, resulting in a static magnetic field having a high magnetic field strength near one side (e.g., “bottom”) of the PEF cavity and a low magnetic field strength (e.g., substantially zero) near the opposite side (e.g., “top”) of the PEF comprising an elongated extraction slit. In one particular embodiment, the one or more permanent magnets are located at a position that is spatially opposed to the location of the elongated extraction slit to achieve the rapidly decaying magnetic field. The magnetic field results in an electron cyclotron frequency in a region of the cavity equal to or approximately equal to a microwave radiation frequency so that plasma is generated to diffuse through the extraction apertures.

Abstract: A method and apparatus is provided for generating a plasma electron flood using microwave radiation. In one embodiment, a microwave PEF apparatus is configured to generate a magnetic field that rapidly decays over a PEF cavity, resulting in a static magnetic field having a high magnetic field strength near one side (e.g., “bottom”) of the PEF cavity and a low magnetic field strength (e.g., substantially zero) near the opposite side (e.g., “top”) of the PEF comprising an elongated extraction slit. In one particular embodiment, the one or more permanent magnets are located at a position that is spatially opposed to the location of the elongated extraction slit to achieve the rapidly decaying magnetic field. The magnetic field results in an electron cyclotron frequency in a region of the cavity equal to or approximately equal to a microwave radiation frequency so that plasma is generated to diffuse through the extraction apertures.

Abstract: Some aspects of the present invention facilitate ion implantation by using a magnetic beam scanner that includes first and second magnetic elements having a beam path region therebetween. One or more magnetic flux compression elements are disposed proximate to the beam path region and between the first and second magnetic elements. During operation, the first and magnetic elements cooperatively generate an oscillatory time-varying magnetic field in the beam path region to scan an ion beam back and forth in time. The one or more magnetic flux compression elements compress the magnetic flux provided by the first and second magnetic elements, thereby reducing the amount of power required to magnetically scan the beam back and forth (relative to previous implementations). Other scanners, systems, and methods are also disclosed.

Abstract: A system and method for magnetically filtering an ion beam during an ion implantation into a workpiece is provided, wherein ions are emitted from an ion source and accelerated the ions away from the ion source to form an ion beam. The ion beam is mass analyzed by a mass analyzer, wherein ions are selected. The ion beam is then decelerated via a decelerator once the ion beam is mass-analyzed, and the ion beam is further magnetically filtered the ion beam downstream of the deceleration. The magnetic filtering is provided by a quadrapole magnetic energy filter, wherein a magnetic field is formed for intercepting the ions in the ion beam exiting the decelerator to selectively filter undesirable ions and fast neutrals.

Abstract: Some aspects of the present disclosure increase throughput beyond what has previously been achievable by changing the scan rate of a scanned ion beam before the entire cross-sectional area of the ion beam extends beyond an edge of a workpiece. In this manner, the techniques disclosed herein help provide greater throughput than what has previously been achievable. In addition, some embodiments can utilize a rectangular (or other non-circularly shaped) scan pattern that allows real-time beam flux measurements to be taken off-wafer during actual implantation. In these embodiments, the workpiece implantation routine can be changed in real-time to account for real-time changes in beam flux. In this manner, the techniques disclosed herein help provide improved throughput and more accurate dosing profiles for workpieces than previously achievable.

Abstract: Some aspects of the present invention facilitate ion implantation by using a magnetic beam scanner that includes first and second magnetic elements having a beam path region therebetween. One or more magnetic flux compression elements are disposed proximate to the beam path region and between the first and second magnetic elements. During operation, the first and magnetic elements cooperatively generate an oscillatory time-varying magnetic field in the beam path region to scan an ion beam back and forth in time. The one or more magnetic flux compression elements compress the magnetic flux provided by the first and second magnetic elements, thereby reducing the amount of power required to magnetically scan the beam back and forth (relative to previous implementations). Other scanners, systems, and methods are also disclosed.

Abstract: A system and method for magnetically filtering an ion beam during an ion implantation into a workpiece is provided, wherein ions are emitted from an ion source and accelerated the ions away from the ion source to form an ion beam. The ion beam is mass analyzed by a mass analyzer, wherein ions are selected. The ion beam is then decelerated via a decelerator once the ion beam is mass-analyzed, and the ion beam is further magnetically filtered the ion beam downstream of the deceleration. The magnetic filtering is provided by a quadrapole magnetic energy filter, wherein a magnetic field is formed for intercepting the ions in the ion beam exiting the decelerator to selectively filter undesirable ions and fast neutrals.

Abstract: One or more aspects of the present invention pertain to a measurement component that facilitates determining a relative orientation between an ion beam and a workpiece. The measurement component is sensitive to ion radiation and allows a relative orientation between the measurement component and the ion beam to be accurately determined by moving the measurement component relative to the ion beam. The measurement component is oriented at a known relationship relative to the workpiece so that a relative orientation between the workpiece and beam can be established. Knowing the relative orientation between the ion beam and workpiece allows the workpiece to be oriented to a specific angle relative to the measured beam angle for more accurate and precise doping of the workpiece, which enhances semiconductor fabrication.

Abstract: One or more aspects of the present invention pertain to stabilizing the current or density of an ion beam within an ion implantation system by selectively adjusting a lone parameter of feed gas flow. Adjusting the gas flow does not necessitate adjustments to other operating parameters and thereby simplifies the stabilization process. This allows the beam current to be stabilized relatively quickly so that ion implantation can begin promptly and continue uninterrupted. This improves throughput while reducing associated implantation costs.

Abstract: An ion beam current density profiler includes a pair of counter-rotating cylindrical masks each featuring a helical slot. The intersection of the slots forms an aperture that scans the width of a ribbon ion beam to allow discrete portions of the beam to impact an inner, concentric current collecting cylinder.

Abstract: Ion implantation scanning systems and methods are presented for providing ions from an ion beam to a treatment surface of a workpiece, wherein a beam is electrically or magnetically scanned in a single direction or plane and an implanted workpiece is rotated about an axis that is at a non-zero angle relative to the beam scan plane, where the workpiece rotation and the beam scanning are synchronized to provide the beam to the workpiece treatment surface at a generally constant angle of incidence.

Abstract: An ion beam implanter includes an ion beam source for generating an ion beam moving along a beam line and a vacuum or implantation chamber wherein a workpiece, such as a silicon wafer is positioned to intersect the ion beam for ion implantation of a surface of the workpiece by the ion beam. A scanning magnet is most preferably used to control a side to side scanning of the ion beam so that an entire implantation surface of the workpiece can be processed.

Abstract: Ion implantation systems and beam containment apparatus therefor are provided in which a photoelectron source and a photon source are provided along a beam path. The photon source, such as a UV lamp, provides photons to a photoemissive material of the photoelectron source to generate photoelectrons for enhanced beam containment in the ion implantation system.