Patent application number | Description | Published |
20080265866 | METHOD AND SYSTEM FOR ION BEAM PROFILING - One embodiment of the invention relates to an apparatus for profiling an ion beam. The apparatus includes a current measuring device having a measurement region, wherein a cross-sectional area of the ion beam enters the measurement region. The apparatus also includes a controller configured to periodically take beam current measurements of the ion beam and to determine a two dimensional profile of the ion beam by relating the beam current measurements to sub-regions within the current measuring device. Other apparatus and methods are also disclosed. | 10-30-2008 |
20090032726 | ION IMPLANTER HAVING COMBINED HYBRID AND DOUBLE MECHANICAL SCAN ARCHITECTURE - A system and method are provided for implanting ions into a workpiece in a plurality of operating ranges. A desired dosage of ions is provided, and a spot ion beam is formed from an ion source and mass analyzed by a mass analyzer. Ions are implanted into the workpiece in one of a first mode and a second mode based on the desired dosage of ions, where in the first mode, the ion beam is scanned by a beam scanning system positioned downstream of the mass analyzer and parallelized by a parallelizer positioned downstream of the beam scanning system. In the first mode, the workpiece is scanned through the scanned ion beam in at least one dimension by a workpiece scanning system. In the second mode, the ion beam is passed through the beam scanning system and parallelizer un-scanned, and the workpiece is two-dimensionally scanned through the spot ion beam. | 02-05-2009 |
20090114815 | PLASMA ELECTRON FLOOD FOR ION BEAM IMPLANTER - A plasma electron flood system, comprising a housing configured to contain a gas, and comprising an elongated extraction slit, and a cathode and a plurality of anodes residing therein and wherein the elongated extraction slit is in direct communication with an ion implanter, wherein the cathode emits electrons that are drawn to the plurality of anodes through a potential difference therebetween, wherein the electrons are released through the elongated extraction slit as an electron band for use in neutralizing a ribbon ion beam traveling within the ion implanter. | 05-07-2009 |
20090321625 | Ion Implanter Having Combined Hybrid and Double Mechanical Scan Architecture - A system and method are provided for implanting ions into a workpiece in a plurality of operating ranges. A desired dosage of ions is provided, and a spot ion beam is formed from an ion source and mass analyzed by a mass analyzer. Ions are implanted into the workpiece in one of a first mode and a second mode based on the desired dosage of ions, where in the first mode, the ion beam is scanned by a beam scanning system positioned downstream of the mass analyzer and parallelized by a parallelizer positioned downstream of the beam scanning system. In the first mode, the workpiece is scanned through the scanned ion beam in at least one dimension by a workpiece scanning system. In the second mode, the ion beam is passed through the beam scanning system and parallelizer un-scanned, and the workpiece is two-dimensionally scanned through the spot ion beam. | 12-31-2009 |
20100012861 | METHOD AND APPARATUS FOR MEASUREMENT OF BEAM ANGLE IN ION IMPLANTATION - An ion beam angle detection apparatus, comprising a linear drive assembly fixedly attached to a moveable profiler assembly, wherein the profiler assembly comprises, a profiler having a profiler aperture formed within a profiler top plate and a profiler sensor assembly, a moveable angle mask assembly comprising a moveable angle mask with a mask aperture, wherein the angle mask assembly is non-fixedly attached to the profiler assembly, the mask aperture is movable relative to the profiler aperture by energizing an mask linear drive fixedly attached to the profiler assembly and the profiler aperture is movable through a length greater than the elongated length of the ion beam. | 01-21-2010 |
20100065761 | ADJUSTABLE DEFLECTION OPTICS FOR ION IMPLANTATION - A deflection component suitable for use in an ion implantation system comprises multiple electrodes that can be selectively biased to cause an ion beam passing therethrough to bend, deflect, focus, converge, diverge, accelerate, decelerate, and/or decontaminate. Since the electrodes can be selectively biased, and thus one or more of them can remain unbiased or off, the effective length of the beam path can be selectively adjusted as desired (e.g., based upon beam properties, such as energy, dose, species, etc.). | 03-18-2010 |
20100084576 | HYBRID SCANNING FOR ION IMPLANTATION - A hybrid scanner is disclosed that is capable of performing at least one of an electric and magnetic scanning of an ion beam. The hybrid scanner comprises a plurality of magnetic elements configured to generate a magnetic field across the ion beam for magnetic scanning, and a plurality of electric elements configured to generate an electric field proximate to the ion beam for electric scanning. A power delivery controller is coupled to at least one of the magnetic elements and at least one of the electric elements, and is configured to selectively provide power to the magnetic and electric elements. | 04-08-2010 |
20100181499 | ENHANCED LOW ENERGY ION BEAM TRANSPORT IN ION IMPLANTATION - An ion implantation method and system that incorporate beam neutralization to mitigate beam blowup, which can be particularly problematic in low-energy, high-current ion beams. The beam neutralization component can be located in the system where blowup is likely to occur. The neutralization component includes a varying energizing field generating component that generates plasma that neutralizes the ion beam and thereby mitigates beam blowup. The energizing field is generated with varying frequency and/or field strength in order to maintain the neutralizing plasma while mitigating the creation of plasma sheaths that reduce the effects of the neutralizing plasma. | 07-22-2010 |
20100308215 | System and Method for Ion Implantation with Improved Productivity and Uniformity - A method comprising introducing an injected gas (e.g., Argon, Xenon) into a beam line region comprising a magnetic scanner is provided herein. The injected gas improves beam current by enhancing (e.g., increasing, decreasing) charge neutralization of the magnetic ion beam (e.g., the ion beam at regions where the scanning magnetic field is non-zero) thereby reducing the current loss due to the zero field effect (ZFE). By reducing the current loss in regions having a magnetic field, the magnetic beam current is increased (e.g., the beam current is increased in regions where the magnetic field is non-zero) raising the overall beam current in a uniform manner over an entire scan path and thereby reducing the effect of the ZFE. In other words, the ZFE is removed by effectively minimizing it through an increase in the magnetized beam current. | 12-09-2010 |
20120248326 | Uniformity of a Scanned Ion Beam - 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. | 10-04-2012 |
20130026356 | System and Method for Ion Implantation with Improved Productivity and Uniformity - A method comprising introducing an injected gas (e.g., Argon, Xenon) into a beam line region comprising a magnetic scanner is provided herein. The injected gas improves beam current by enhancing (e.g., increasing, decreasing) charge neutralization of the magnetic ion beam (e.g., the ion beam at regions where the scanning magnetic field is non-zero) thereby reducing the current loss due to the zero field effect (ZFE). By reducing the current loss in regions having a magnetic field, the magnetic beam current is increased (e.g., the beam current is increased in regions where the magnetic field is non-zero) raising the overall beam current in a uniform manner over an entire scan path and thereby reducing the effect of the ZFE. In other words, the ZFE is removed by effectively minimizing it through an increase in the magnetized beam current. | 01-31-2013 |
20130146760 | SYSTEM AND METHOD FOR ION IMPLANTATION WITH IMPROVED PRODUCTIVITY AND UNIFORMITY - 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. | 06-13-2013 |
20130181139 | BEAM LINE DESIGN TO REDUCE ENERGY CONTAMINATION - 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. | 07-18-2013 |