Abstract: An ion implantation system and method are provided where an ion beam is tuned to a first process recipe. The ion beam is scanned along a scan plane at a first frequency, defining a first scanned ion beam. A beam profiling apparatus is translated through the first scanned ion beam and one or more properties of the first scanned ion beam are measured across a width of the first scanned ion, thus defining a first beam profile associated with the first scanned ion beam. The ion beam is then scanned at a second frequency, thus defining a second scanned ion beam, wherein the second frequency is less than the first frequency. A second beam profile associated with the second scanned ion beam is determined based, at least in part, on the first beam profile. Ions are subsequently implanted into a workpiece via the second scanned ion beam.

Abstract: An ion implantation system has an ion source forming an ion beam. An mass analyzer defines and varies a mass analyzed beam along a beam path. A moveable mass resolving aperture assembly has a resolving aperture whose position is selectively varied in response to the variation of the beam path by the mass analyzer. A deflecting deceleration element positioned selectively deflects the beam path and selectively decelerate the mass analyzed beam. A controller selectively operates the ion implantation system in both a drift mode and decel mode. The controller passes the mass analyzed beam along a first path through the resolving aperture without deflection or deceleration in the drift mode and deflects and decelerates the beam along a second path in the decel mode. The position of the resolving aperture is selectively varied based on the variation in the beam path through the mass analyzer and the deflecting deceleration element.

Abstract: A system and method are provided for implanting ions at low energies into a workpiece. An ion source configured to generate an ion beam is provided, wherein a mass resolving magnet is configured to mass resolve the ion beam. The ion beam may be a ribbon beam or a scanned spot ion beam. A mass resolving aperture positioned downstream of the mass resolving magnet filters undesirable species from the ion beam. A combined electrostatic lens system is positioned downstream of the mass analyzer, wherein a path of the ion beam is deflected and contaminants are generally filtered out of the ion beam, while concurrently decelerating and parallelizing the ion beam. A workpiece scanning system is further positioned downstream of the combined electrostatic lens system, and is configured to selectively translate a workpiece in one or more directions through the ion beam, therein implanting ions into the workpiece.

Abstract: A combined scanning and focusing magnet for an ion implantation system is provided. The combined scanning and focusing magnet has a yoke having a high magnetic permeability. The yoke defines a hole configured to pass an ion beam therethrough. One or more scanner coils operably are coupled to the yoke and configured to generate a time-varying predominantly dipole magnetic field when electrically coupled to a power supply. One or more focusing coils are operably coupled to the yoke and configured to generate a predominantly multipole magnetic field, wherein the predominantly multipole magnetic field is one of static or time-varying.

Abstract: An ion implantation system and method are provided where an ion beam is tuned to a first process recipe. The ion beam is scanned along a scan plane at a first frequency, defining a first scanned ion beam. A beam profiling apparatus is translated through the first scanned ion beam and one or more properties of the first scanned ion beam are measured across a width of the first scanned ion, thus defining a first beam profile associated with the first scanned ion beam. The ion beam is then scanned at a second frequency, thus defining a second scanned ion beam, wherein the second frequency is less than the first frequency. A second beam profile associated with the second scanned ion beam is determined based, at least in part, on the first beam profile. Ions are subsequently implanted into a workpiece via the second scanned ion beam.

Abstract: A combined scanning and focusing magnet for an ion implantation system is provided. The combined scanning and focusing magnet has a yoke having a high magnetic permeability. The yoke defines a hole configured to pass an ion beam therethrough. One or more scanner coils operably are coupled to the yoke and configured to generate a time-varying predominantly dipole magnetic field when electrically coupled to a power supply. One or more focusing coils are operably coupled to the yoke and configured to generate a predominantly multipole magnetic field, wherein the predominantly multipole magnetic field is one of static or time-varying.

Abstract: An ion implantation system employs a mass analyzer for both mass analysis and angle correction. An ion source generates an ion beam along a beam path. A mass analyzer is located downstream of the ion source that performs mass analysis and angle correction on the ion beam. A resolving aperture within an aperture assembly is located downstream of the mass analyzer component and along the beam path. The resolving aperture has a size and shape according to a selected mass resolution and a beam envelope of the ion beam. An angle measurement system is located downstream of the resolving aperture and obtains an angle of incidence value of the ion beam. A control system derives a magnetic field adjustment for the mass analyzer according to the angle of incidence value of the ion beam from the angle measurement system.

Abstract: A system and method are provided for implanting ions at low energies into a workpiece. An ion source configured to generate an ion beam is provided, wherein a mass resolving magnet is configured to mass resolve the ion beam. The ion beam may be a ribbon beam or a scanned spot ion beam. A mass resolving aperture positioned downstream of the mass resolving magnet filters undesirable species from the ion beam. A combined electrostatic lens system is positioned downstream of the mass analyzer, wherein a path of the ion beam is deflected and contaminants are generally filtered out of the ion beam, while concurrently decelerating and parallelizing the ion beam. A workpiece scanning system is further positioned downstream of the combined electrostatic lens system, and is configured to selectively translate a workpiece in one or more directions through the ion beam, therein implanting ions into the workpiece.

Abstract: Methods and apparatus for reducing energy contamination can be provided to a beam line assembly for ion implantation. Protrusions comprising surface areas and grooves therebetween can face neutral trajectories within a line of sight view from the workpiece within the beam line assembly. The protrusions can alter the course of the neutral trajectories away from the workpiece or cause alternate trajectories for further impacting before hitting a workpiece, and thereby, further reduce energy contamination for more sensitive implants.

Abstract: Beam current is adjusted during ion implantation by adjusting one or more parameters of an ion source. The ion beam is generated or provided by a non-arc discharge based ion source, such as an electron gun driven ion source or an RF driven ion source. A beam current adjustment amount is determined. Then, one or more parameters of the ion source are adjusted according to the determined beam current adjustment amount. The beam current is provided having a modulated beam current.

Abstract: The present invention relates to a method and apparatus for varying the cross-sectional shape of an ion beam, as the ion beam is scanned over the surface of a workpiece, to generate a time-averaged ion beam having an improved ion beam current profile uniformity. In one embodiment, the cross-sectional shape of an ion beam is varied as the ion beam moves across the surface of the workpiece. The different cross-sectional shapes of the ion beam respectively have different beam profiles (e.g., having peaks at different locations along the beam profile), so that rapidly changing the cross-sectional shape of the ion beam results in a smoothing of the beam current profile (e.g., reduction of peaks associated with individual beam profiles) that the workpiece is exposed to. The resulting smoothed beam current profile provides for improved uniformity of the beam current and improved workpiece dose uniformity.

Abstract: A scanning system including a scanning element, a beam profiler, analysis system, and a ZFE-limiting element, is disclosed. The scanning element is configured to scan an ion beam over an ion beam scan path. The beam profiler measures beam current of the ion beam as it is scanned over the ion beam scan path, and the analysis system analyzes the measured beam current to detect a ZFE condition. The ZFE-limiting element, which is upstream of the beam profiler and is coupled to the analysis system via a feedback path, is configured to selectively apply an electric field to the scanned ion beam based on whether the ZFE condition is detected. The selectively applied electric field induces a change in the scanned beam to limit the ZFE condition.

Abstract: Methods and apparatus for reducing energy contamination can be provided to a beam line assembly for ion implantation. Protrusions comprising surface areas and grooves therebetween can face neutral trajectories within a line of sight view from the workpiece within the beam line assembly. The protrusions can alter the course of the neutral trajectories away from the workpiece or cause alternate trajectories for further impacting before hitting a workpiece, and thereby, further reduce energy contamination for more sensitive implants.

Abstract: A scanning system including a scanning element, a beam profiler, analysis system, and a ZFE-limiting element, is disclosed. The scanning element is configured to scan an ion beam over an ion beam scan path. The beam profiler measures beam current of the ion beam as it is scanned over the ion beam scan path, and the analysis system analyzes the measured beam current to detect a ZFE condition. The ZFE-limiting element, which is upstream of the beam profiler and is coupled to the analysis system via a feedback path, is configured to selectively apply an electric field to the scanned ion beam based on whether the ZFE condition is detected. The selectively applied electric field induces a change in the scanned beam to limit the ZFE condition.

Abstract: The present invention relates to a method and apparatus for varying the cross-sectional shape of an ion beam, as the ion beam is scanned over the surface of a workpiece, to generate a time-averaged ion beam having an improved ion beam current profile uniformity. In one embodiment, the cross-sectional shape of an ion beam is varied as the ion beam moves across the surface of the workpiece. The different cross-sectional shapes of the ion beam respectively have different beam profiles (e.g., having peaks at different locations along the beam profile), so that rapidly changing the cross-sectional shape of the ion beam results in a smoothing of the beam current profile (e.g., reduction of peaks associated with individual beam profiles) that the workpiece is exposed to. The resulting smoothed beam current profile provides for improved uniformity of the beam current and improved workpiece dose uniformity.

Abstract: One embodiment relates to an ion implanter. The ion implanter includes an ion source to generate an ion beam, as well as a scanner to scan the ion beam across a surface of a workpiece along a first axis. The ion implanter also includes a deflection filter downstream of the scanner to ditheredly scan the ion beam across the surface of the workpiece along a second axis.

Abstract: The present invention relates to a method and apparatus for varying the cross-sectional shape of an ion beam, as the ion beam is scanned over the surface of a workpiece, to generate a time-averaged ion beam having an improved ion beam current profile uniformity. In one embodiment, the cross-sectional shape of an ion beam is varied as the ion beam moves across the surface of the workpiece. The different cross-sectional shapes of the ion beam respectively have different beam profiles (e.g., having peaks at different locations along the beam profile), so that rapidly changing the cross-sectional shape of the ion beam results in a smoothing of the beam current profile (e.g., reduction of peaks associated with individual beam profiles) that the workpiece is exposed to. The resulting smoothed beam current profile provides for improved uniformity of the beam current and improved workpiece dose uniformity.

Abstract: One embodiment relates to an ion implanter. The ion implanter includes an ion source to generate an ion beam, as well as a scanner to scan the ion beam across a surface of a workpiece along a first axis. The ion implanter also includes a deflection filter downstream of the scanner to ditheredly scan the ion beam across the surface of the workpiece along a second axis.

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: Ion implantation systems and scanning systems are provided, in which a focus adjustment component is provided to adjust a focal property of an ion beam to diminish zero field effects of the scanner upon the ion beam. The focal property may be adjusted in order to improve the consistency of the beam profile scanned across the workpiece, or to improve the consistency of the ion implantation across the workpiece. Methods are disclosed for providing a scanned ion beam to a workpiece, comprising scanning the ion beam to produce a scanned ion beam, adjusting a focal property of an ion beam in relation to zero field effects of the scanner upon the ion beam, and directing the ion beam toward the workpiece.