Patent Number: 
Section: claims

1. A method of quenching an arc in an ion implantation system and repainting the ion beam to recover any dose loss during such arcing using an arc quenching circuit associated with a high voltage supply for an electrode of the ion implantation system comprising:horizontally scanning a wafer in front of the ion beam;vertically scanning the wafer in front of the ion beam;detecting a current or voltage change associated with the arc at the electrode;monitoring horizontal and vertical scan motions to obtain initial and final scan positions associated with the detection of the arc;controlling a HV switch connected between the high voltage supply and the electrode to open when the arc is detected in order to interrupt the high voltage supply to the electrode and to quench the arc;controlling the HV switch to close when the arc is not detected in order to connect the high voltage supply to the electrode and to reestablish the ion beam; andrepainting the ion beam after an arc, the repainting process comprising:disabling the ion beam by opening the HV switch;moving the wafer to the initial or final scan position associated with the detection of the arc, and closing the HV switch to enable the ion beam; andscanning the wafer horizontally and vertically in front of the ion beam until the other of the initial or final scan position associated with the detection of the arc is encountered, and opening the HV switch to disable the ion beam. 2. The method of claim 1, further comprising synchronizing two or more arc quenching circuits having two or more high voltage switches used to quench an arc between the electrodes of two or more respective high voltage power supplies for the ion implanter, and repainting the ion beam after an arc from the electrodes. 3. The method of claim 1, further comprising monitoring a time duration of the detected arc, and wherein the repainting process is only accomplished if the time duration of the arc detected is longer than a predetermined interval. 4. The method of claim 1, wherein the repainting process is delayed until the ion beam scan returns to a wafer exchange position of the wafer. 5. The method of claim 1, wherein the repainting process is delayed until the ion beam scan completes a current horizontal scan movement. 6. The method of claim 1, wherein the horizontal and vertical scanning continue after the detection of an arc. 7. The method of claim 6, wherein the repainting process is delayed until the end of the ion beam scans, wherein one or more arc detections may be repainted collectively during one or more continuous scan movements. 8. The method of claim 1, wherein the ion beam is forced on or off by the HV switch. 9. The method of claim 1, wherein the HV switch is opened for a predetermined time period following the detection of the arc. 10. The method of claim 1, wherein monitoring the horizontal and vertical scan positions associated with the detection of an arc, comprises monitoring motion encoders coupled to horizontal and vertical scan motors, and storing encoder position data associated with the initial detection of the arc, and the final detection of the arc. 11. The method of claim 1, wherein the ion beam is forced on or off in response to a beam duty factor command from the ion implantation system or a motion control system to disable the ion beam during one of, arrival at a wafer load or unload position, a manual beam OFF switch operation, and a wafer exchange, and to enable the ion beam during one of, a manual beam ON switch operation, subsequent to a wafer exchange, following a load operation, and upon a command to implant another wafer. 12. The method of claim 1, wherein the repainting process further comprises:monitoring a time duration of the detected arc, and repainting only if the time duration of the detected arc is longer than a predetermined interval;continuously scanning the wafer vertically and horizontally in front of the ion beam;forcing the HV switch open to disable the ion beam for a predetermined time that is longer than any anticipated arc duration;forcing the HV switch closed again such that the ion beam recovers;forcing the HV switch to open after completing a requested wafer scan;moving the wafer to the initial scan position associated with the detection of the arc in preparation for the repaint;closing the HV switch to enable the ion beam; andrepainting by scanning the wafer horizontally and vertically in front of the ion beam until the final scan position associated with the detection of the arc is encountered, and opening the HV switch to disable the ion beam. 13. A method of quenching an arc in an ion implantation system having an arc quenching circuit used in association with a high voltage supply for an electrode of the ion implantation system comprising:detecting a current or voltage change associated with the arc at the electrode;monitoring horizontal and vertical scan motions associated with the ion beam and a wafer being scanned by the ion implanter to obtain initial and final scan positions associated with the detection of the arc;controlling a HV switch connected between the high voltage supply and the electrode to open when the arc is detected in order to interrupt an arc current to the electrode and to quench the arc; andcontrolling the HV switch to close when the arc is not detected in order to connect the high voltage supply to the electrode and to establish the ion beam. 14. The method of claim 13 wherein the horizontal and vertical scanning continue after the detection of an arc. 15. The method of claim 13 wherein monitoring the horizontal and vertical scan positions associated with the detection of an arc, comprises monitoring motion encoders coupled to horizontal and vertical scan motors, and storing encoder position data associated with the initial detection of the arc, and the final detection of the arc. 16. The method of claim 13, further comprising synchronizing two or more arc quenching circuits having two or more high voltage switches used to quench an arc between the electrodes of two or more respective high voltage power supplies for the ion implanter, and repainting the ion beam after an arc from the electrodes. 17. An ion implantation system comprising:an ion source for producing a quantity of ions which can be extracted in the form of an ion beam, the ion beam having a beam current;one or more high voltage switches, each switch connected in series with a high voltage power supply for a respective electrode associated with the implanter, each high voltage switch operable to interrupt and reestablish a current to the respective electrode to quench an arc produced within the ion implantation system;a trigger control circuit coupled to the one or more high voltage switches, operable to detect a current or voltage change associated with at least one of the electrodes and to control the respective one or more high voltage switches to open or close based on the detection and an initial and final scan position associated with the arc; andone or more protection circuits, each protection circuit associated with one of the high voltage switches, operable to absorb energy from reactive elements external to the respective high voltage switch, and to limit an over-voltage across the respective high voltage switch. 18. A method of repainting an ion beam to a wafer in an ion implantation system following detection and quenching of an arc using an arc quenching circuit associated with a high voltage supply for an extraction electrode of the ion implantation system to recover any dose loss during such arcing, the repainting method comprising:scanning the wafer in front of the ion beam using horizontal and vertical scan motions;detecting a current or voltage change associated with the arc;monitoring the wafer scan motions to obtain an initial scan position associated with the detection of the arc;controlling a HV switch of the arc quenching circuit connected between the high voltage power supply and the electrode to open when the arc is detected in order to interrupt the power to the electrode and to quench the arc;monitoring the wafer scan motions to obtain a final scan position associated with the detection of the arc, wherein the arc is no longer detected; andcontrolling the HV switch to close when the arc is not detected in order to reconnect the high voltage supply to the electrode and to reestablish the ion beam. 19. The method of claim 18, wherein the HV switch of the arc quenching circuit is held open for a predetermined time period after the arc is initially detected and before controlling the HV switch to close when the arc is not detected. 20. The method of claim 19, further comprising repainting the wafer in front of the ion beam after the end of the wafer scans, the repainting comprising;disabling the ion beam by opening the HV switch;moving the wafer to the initial or final scan position associated with the detection of the arc, and closing the HV switch to enable the ion beam; andscanning the wafer in front of the ion beam until the other of the initial or final scan positions associated with the detection of the arc is encountered, and opening the HV switch to disable the ion beam. 21. The method of claim 20, wherein one or more arc detections is repainted collectively during one or more continuous scan motions. 22. The method of claim 18, further comprising repainting the ion beam after the arc detection, the repainting process comprising:disabling the ion beam at the initial scan position associated with the detection of the arc by opening the HV switch;continue scanning the wafer until the end of the present horizontal scan motion and the final scan position associated with the detection of the arc;enabling the ion beam by closing the HV switch;scanning the wafer in front of the ion beam from the final scan position associated with the detection of the arc toward the initial scan position associated with the detection of the arc,disabling the ion beam at the initial scan position associated with the detection of the arc by opening the HV switch;scanning the wafer in front of the ion beam until the final scan position associated with the detection of the arc is again encountered, and closing the HV switch to enable the ion beam; andscanning the wafer in front of the ion beam until the end of the wafer scans, and opening the HV switch to disable the ion beam. 23. The method of claim 18, further comprising synchronizing two or more arc quenching circuits having two or more high voltage switches used to quench an arc between the electrodes of two or more respective high voltage power supplies for the ion implanter, and repainting the ion beam after an arc from the electrodes. 24. The method of claim 18, further comprising monitoring a time duration of the detected arc, and wherein the repainting process is only accomplished if the time duration of the arc detected is longer than a predetermined interval. 25. The method of claim 18, wherein the repainting process is delayed until the ion beam scan returns to a wafer exchange position. 26. The method of claim 18, wherein the repainting process is delayed until the ion beam scan completes a current horizontal scan movement. 27. The method of claim 18, wherein the repainting process is delayed until the end of the wafer scans, wherein one or more arc detections may be repainted collectively during one or more continuous scan movementsdisabling the ion beam by opening the HV switch;moving the wafer to the initial or final scan position associated with the detection of the arc, and closing the HV switch to enable the ion beam; andscanning the wafer in front of the ion beam until the other of the initial or final scan positions associated with the detection of the arc is encountered, and opening the HV switch to disable the ion beam. 28. The method of claim 18, wherein monitoring the horizontal and vertical scan positions associated with the detection of an arc, comprises monitoring motion encoders coupled to horizontal and vertical scan motors, and storing encoder position data associated with the initial detection of the arc, and the final detection of the arc. 29. The method of claim 18, wherein the ion beam is forced on or off in response to a beam duty factor command from the ion implantation system or a motion control system to disable the ion beam during one of, arrival at a wafer load or unload position, a manual beam OFF switch operation, and a wafer exchange, and to enable the ion beam during one of, a manual beam ON switch operation, subsequent to a wafer exchange, following a load operation, and upon a command to implant another wafer. 30. A method of quenching an arc associated with an ion beam in an extraction system of an ion source comprising:detecting a current or voltage change associated with the arc within the extraction system;monitoring horizontal and vertical scan motions to obtain initial and final scan positions associated with the detection of the arc;controlling a high voltage switch connected between a high voltage supply and the extraction system to open when the arc is detected in order to interrupt the high voltage supply to the electrode and to quench the arc; andcontrolling the HV switch to close when the arc is not detected in order to reconnect the high voltage supply to the extraction system and to reestablish the ion beam. 31. The method of claim 30 further comprising: scanning a wafer in front of the ion beam using horizontal and vertical scan motions. 32. The method of claim 31, further comprising repainting the wafer in front of the ion beam after the arc has been detected and the ion beam has been reestablished, the repainting comprising:disabling the ion beam by opening the high voltage switch;moving the wafer to the initial or final scan position associated with the detection of the arc, and closing the high voltage switch to enable the ion beam; andscanning the wafer in front of the ion beam until the other of the initial or final scan positions associated with the detection of the arc is encountered, and opening the high voltage switch to disable the ion beam. 33. The method of claim 30, wherein the high voltage switch is held open for a predetermined time period after the arc is initially detected and before controlling the HV switch to close when the arc is not detected. 34. The system of claim 17, further comprising a synchronization circuit operable to synchronize and time two or more trigger control circuits for the opening and closing of two or more high voltage switches for the ion implantation system.