Abstract: A method derives a terminal return current or upstream current to adjust and/or compensate for variations in beam current during ion implantation. One or more individual upstream current measurements are obtained from a region of an ion implantation system. A terminal return current, or composite upstream current, is derived from the one or more current measurements. The terminal return current is then employed to adjust scanning or dose of an ion beam in order to facilitate beam current uniformity at a target wafer.

Abstract: One embodiment of the invention relates to a method for adjusting the ribbon beam flux of a scanned ion beam. In this method, an ion beam is scanned at a scan rate, and a plurality of dynamic beam profiles are measured as the ion beam is scanned. A corrected scan rate is calculated based on the plurality of measured dynamic beam profiles of the scanned beam. The ion beam is scanned at the corrected scan rate to produce a corrected ribbon ion beam. Other methods and systems are also disclosed.

Abstract: A system and method for mitigating contamination in an ion implantation system is provided. The system comprises an ion source, a power supply operable to supply power to a filament and mirror electrode of the ion source, a workpiece handling system, and a controller, wherein the ion source is selectively tunable via the controller to provide rapid control of a formation of an ion beam. The controller is operable to selectively rapidly control power to the ion source, therein modulating a power of the ion beam between an implantation power and a minimal power in less than approximately 20 microseconds based, at least in part, to a signal associated with a workpiece position. Control of the ion source therefore mitigates particle contamination in the ion implantation system by minimizing an amount of time at which the ion beam is at the implantation current.

Abstract: A system, method, and apparatus for mitigating contamination during ion implantation are provided. An ion source, end station, and mass analyzer positioned between the ion source and the end station are provided, wherein an ion beam is formed from the ion source and travels through the mass analyzer to the end station. An ion beam dump assembly comprising a particle collector, particle attractor, and shield are associated with the mass analyzer, wherein an electrical potential of the particle attractor is operable to attract and constrain contamination particles within the particle collector, and wherein the shield is operable to shield the electrical potential of the particle attractor from an electrical potential of an ion beam within the mass analyzer.

Abstract: A deposit cleaning system for removing deposits from interior surfaces of ion sources and/or electrodes includes a fluorine source, a throttle mechanism, and a controller. The fluorine source supplies fluorine to the ion source as a cleaning material. The throttle mechanism mitigates loss of fluorine through a source aperture of the ion source by at least partially covering the source aperture. The controller controls the supply and flow rate from the fluorine source to the ion source and also controls the positioning of the throttle mechanism.

Abstract: An ion source includes a first plasma chamber including a plasma generating component and a first gas inlet for receiving a first gas such that said plasma generating component and said first gas interact to generate a first plasma within said first plasma chamber, wherein said first plasma chamber further defines an aperture for extracting electrons from said first plasma, and a second plasma chamber including a second gas inlet for receiving a second gas, wherein said second plasma chamber further defines an aperture in substantial alignment with the aperture of said first plasma chamber, for receiving electrons extracted therefrom, such that the electrons and the second gas interact to generate a second plasma within said second plasma chamber, said second plasma chamber further defining an extraction aperture for extracting ions from said second plasma.

Abstract: An ion implantation system for providing a mass analyzed ribbon beam that comprises an ion beam source that includes a plasma source and an extraction component, wherein the extraction component is configured to extract a diverging ion beam and direct the ion beam to a window frame magnet assembly. The window frame magnet assembly comprises two pairs of coils orthogonally arranged within a window shaped yoke to produce an independently controllable uniform cross-field magnetic field. The first set of coils create an uniform field across the width of the diverging beam to convert it to a uniform parallel broad ion beam. The second set of coils bend the sheet of the ion beam in orthogonal direction to give mass dispersion for ion mass selection.

Abstract: A contamination mitigation or surface modification system for ion implantation processes includes a gas source, a controller, a valve, and a process chamber. The gas source provides delivery of a gas, be it atmospheric or reactive, to the valve and is controlled by the controller. The valve is located on or about the process chamber and controllably adjusts flow rate and/or composition of the gas to the process chamber. The process chamber holds a target device, such as a target wafer and permits interaction of the gas with an ion beam to mitigate contamination of the target wafer and/or to modify the existing properties of the processing environment or target device to change a physical or chemical state or characteristic thereof. The controller selects and adjusts composition of the gas and flow rate according to contaminants present within the ion beam, or lack thereof, as well total or partial pressure analysis.

Abstract: The present invention is directed to a switch circuit and method to quickly enable or disable the ion beam to a wafer within an ion implantation system. The beam control technique may be applied to wafer doping repaint and duty factor reduction. The circuit and method may be used to quench an arc that may form between high voltage electrodes associated with an ion source to shorten the duration of the arc and mitigate non-uniform ion implantations. The circuit and method facilitates repainting the ion beam over areas where an arc was detected to recover dose loss during such arcing. A high voltage high speed switching circuit is added between each high voltage supply and its respective electrode to quickly extinguish the arc to minimize disruption of the ion beam. The high voltage switch is controlled by a trigger circuit which detects voltage or current changes to each electrode. Protection circuits for the HV switch absorb energy from reactive components and clamp any overvoltages.

Abstract: A parallelizing component of an ion implantation system comprises two angled dipole magnets that mirror one another and serve to bend an ion beam traversing therethrough to have a substantially “s” shape. This s bend serves to filter out contaminants of the beam, while the dipoles also parallelize the beam to facilitate uniform implant properties across the wafer, such as implant angle, for example. Additionally, a deceleration stage is included toward the end of the implantation system so that the energy of the beam can be kept relatively high throughout the beamline to mitigate beam blowup.

Abstract: The present invention involves a workpiece gripping integrity device or method comprising a charge-transfer sensing device, configured to detect a change in charge associated with the gripper arm assembly based on a grip condition thereof.

Abstract: A system, apparatus, and method for changing source gases used for ion implantation is provided. A source chamber has a housing having one or more sidewalls and an extraction plate, wherein the one or more sidewalls and the extraction plate enclose an interior region of the source chamber. One or more inlets provide a fluid communication between one or more ignitable material sources and the interior region. An extraction aperture in the extraction plate provides a fluid communication between the interior region of the source chamber and a beam path region external to the source chamber. One or more diffusion apertures in the one or more sidewalls of the housing further provide a fluid communication between the interior region and a diffusion region external to the ion source chamber, wherein deposited ions are operable to diffuse out of the source chamber through the diffusion apertures.

Abstract: An elevated temperature RF ion source system, comprising an ion source body, an RF antenna coil external to the ion source body, a vacuum enclosure surrounding both the outside surface of the ion source body and the RF antenna coil, at least one power supply, a gas delivery system operatively coupled to the ion source body, a vacuum condition between the outside surface of the ion source body and the RF antenna coil, the RF antenna coil operatively coupled to the at least one power supply, and a water cooling system operatively coupled to the RF antenna coil and the vacuum enclosure.

Abstract: A method is provided for heating a substrate in a process chamber using a heated chuck. In accordance with the method, the substrate is lowered onto the chuck and heated to a first temperature less than a temperature of the chuck. The substrate is then raised away from the chuck, and a process is carried out on the substrate while the substrate is supported above the chuck. The substrate is then lowered back to the chuck and heated to a second temperature greater than the first temperature for further processing of the substrate.

Abstract: An angle measurement system for measuring angles of incidence for ion beams during ion implantation includes a varied angle slot array and an array of charge measurement devices located downstream of the varied angle slot array. The varied angle slot array includes slots formed within a structure from an entrance surface to an exit surface. Each of the slots has a varied acceptance angle range. The array of charge measurement devices are individually associated with the slots and can measure charge or beam current for beamlets that pass through the slots. These measurements and the varied or different acceptance angle ranges can then be employed to determine a measured angle of incidence and/or angular content for an ion beam.

Abstract: An ion implantation apparatus, system, and method for controlling an ion beam, wherein a mass analyzer generally positioned between an ion source and an end station is configured to selectively control a path of a desired ion beam. The mass analyzer comprises one or more of an entrance pole mechanism positionable proximate to an entrance of the mass analyzer and an exit pole mechanism positionable proximate to an exit of the mass analyzer, wherein the position of the entrance pole mechanism and exit pole mechanism generally determines the path and focal point of the desired ion beam. A controller is configured to selectively position one or more of the entrance pole mechanism and exit pole mechanism, therein generally controlling the path of the desired ion beam at the exit of the mass analyzer, wherein the control may be based on one or more detected characteristics of the desired ion beam.

Abstract: An ion implantation system utilizing detected ion induced luminescence as feedback control that comprises, a wafer, a spectrometer, a photodetector, an ion source generator, wherein the ion source generator is configured to implant the wafer with ions, and the photodetector is configured to detect ion induced luminescence both on and off the wafer.

Abstract: An ion implanter includes an ion 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. An ion source includes a ionization chamber and an ionization chamber electrode defining an ionization chamber aperture, wherein the ionization chamber electrode includes a raised portion for generating substantially uniform electric fields in the region adjacent the ionization chamber electrode.

Abstract: The present invention is directed to aligning wafers within semiconductor fabrication tools. More particularly, one or more aspects of the present invention pertain to quickly and efficiently finding an alignment marking, such as an alignment notch, on a wafer to allow the wafer to be appropriately oriented within an alignment tool. Unlike conventional systems, the notch is located without firmly holding and spinning or rotating the wafer. Exposure to considerable backside contaminants is thereby mitigated and the complexity and/or cost associated with aligning the wafer is thereby reduced.

Abstract: A plasma ashing process for removing photoresist material and post etch residues from a substrate comprising carbon, hydrogen, or a combination of carbon and hydrogen, wherein the substrate comprises a low k dielectric layer, the process comprising forming a plasma from an essentially oxygen free and nitrogen free gas mixture; introducing the plasma into a process chamber, wherein the process chamber comprises a baffle plate assembly in fluid communication with the plasma; flowing the plasma through the baffle plate assembly and removing photoresist material, post etch residues, and volatile byproducts from the substrate; periodically cleaning the process chamber by introducing an oxygen plasma into the process chamber; and cooling the baffle plate assembly by flowing a cooling gas over the baffle plate assembly.