Patent Number: 
Section: claims

1. An ion implantation system comprising:an ion implanter configured to produce a ribbon-like ion beam;an AEF system configured to filter an energy of the ribbon-like ion beam by bending the beam at a final energy bend; an AEF dose cup associated with the AEF system, and configured to measure ion beam current substantially immediately following the final energy bend; andan end station downstream of the AEF system, the end station defined by a chamber wherein a workpiece is secured in place for movement relative to the ribbon-like ion beam for implantation of ions therein;wherein the AEF dose cup is located external to the end station chamber. 2. The system of claim 1, wherein the AEF system comprises:a pair of deflection plates to deflect the ion beam by a target angle of deflection, thereby defining a final energy level of the ion beam corresponding to the angle of deflection from an original path;a set of suppression electrodes downstream of the deflection plates, the electrodes configured to terminate a positive potential imparted to the ion beam by the deflection plates and a beam dump plate to absorb energy of neutral particles in the beam not deflected by the deflection plates; andthe AEF dose cup immediately following the final energy bend in the ion beam for measuring the ion current in the beam before a substantial portion of the ion beam can become neutralized. 3. The system of claim 1, wherein the final energy level of the ion beam corresponds to an angle of deflection of about 15 degrees from the original path. 4. The system of claim 1, wherein the AEF dose cup is located in an overscan region in relationship to the area of the workpiece scanned by the ribbon-like ion beam. 5. The system of claim 1, wherein the plane of the final energy bend in the ion beam is orthogonal to the plane of the ribbon-like ion beam. 6. The system of claim 1, wherein the AEF dose cup is located within the AEF system located in an AEF chamber region, wherein a pressure is reduced by a pump below a pressure of the end station downstream from the AEF chamber. 7. The system of claim 1, further comprising a dose compensation control system, wherein the AEF dose cup measurement is used to control the scan velocity of the workpiece across the ion beam. 8. The system of claim 7, further comprising pressure compensation to correct the AEF dose cup measurements, the pressure compensation comprising:a pressure sensor operable to measure a pressure associated with the implantation system in the AEF system located external to the end station chamber, the sensor having an output connected to the compensation control system to correct the scan velocity based on the pressure measured;one of a compensation circuit, and a compensation software routine adapted to determine a pressure compensation factor as a function of the measured pressure and the measured ion beam current; anda scan motion control system operable to control a scan velocity of the workpiece across the ion beam based on the pressure measured and the pressure compensation factor. 9. The system of claim 8, wherein the AEF system is located in an AEF chamber region external to the end station chamber, and wherein the pressure within the AEF chamber is further reduced by a pump below the pressure of the end station chamber downstream from the AEF chamber to further reduce the effect of outgassing and pressure on the AEF cup. 10. The system of claim 1, wherein readings from a dose cup near the workpiece are compared to those of the AEF cup during an implant to deduce the charge exchange rate difference between the two positions, thereby enabling a determination of the number of neutral particles produced over the corresponding path length. 11. The system of claim 1, wherein the ion current measured at the AEF dose cup is proportional to the current going to the workpiece. 12. The system of claim 1, wherein the ion current implanted at the workpiece is determined to be proportional to the current measured in the AEF dose cup by a scaling factor Cp according to the relationship:Iimplanted=IAEF*Cp. 13. The system of claim 12, wherein Cp is calculated based on readings of the AEF cup and an End Station cup to determine the fraction of charge exchange affecting the AEF cup and to compensate the readings for pressure changes. 14. The system of claim 1, wherein the ribbon-like ion beam is a scanned ion beam. 15. The system of claim 1, wherein the ribbon-like ion beam is a continuous ion beam. 16. The system of claim 1, wherein the AEF dose cup measures the ion current associated with final energy of the beam at a location before the beam traverses a greater portion of the distance of the beam path toward the workpiece. 17. The system of claim 16, wherein the AEF dose cup is located nearer to the final energy bend in the ion beam than to the workpiece. 18. The system of claim 1, wherein the AEF dose cup is located nearer to the final energy bend in the ion beam than to the workpiece. 19. The system of claim 16, wherein the AEF dose cup is located at a position wherein measurements of the ion current associated with final energy of the beam are made before the beam has subsequently exchanged a greater portion of the ions of the beam on the path toward the workpiece. 20. The system of claim 1, wherein the AEF dose cup is located at a position wherein measurements of the ion current associated with final energy of the beam are made before the beam has subsequently exchanged a significant portion of the ions of the beam on the path toward the workpiece. 21. An ion implantation system comprising:an ion implanter configured to produce one of a scanned or ribbon-like ion beam;an AEF system configured to filter an energy of the ion beam by bending the beam at a final energy bend; an AEF dose cup associated with the AEF system, and configured to measure ion beam current, the AEF dose cup located following the final energy bend nearer to the final energy bend than to a workpiece; andan end station downstream of the AEF system, the end station defined by a chamber wherein the workpiece is secured in place and provides movement relative to the ribbon-like ion beam for implantation of ions therein;wherein the AEF dose cup is located external to the end station chamber. 22. The system of claim 21, wherein the AEF system comprises:a pair of deflection plates to deflect the ion beam by a target angle of deflection, thereby defining a final energy level of the ion beam corresponding to the angle of deflection from an original path;a set of suppression electrodes downstream of the deflection plates, the electrodes-configured to terminate a positive potential imparted to the ion beam by the deflection plates; andthe AEF dose cup immediately following the final energy bend in the ion beam for measuring the ion current in the beam before a substantial portion of the ion beam can become neutralized. 23. The system of claim 21, wherein the final energy level of the ion beam corresponds to an angle of deflection of about 15 degrees from the original path. 24. The system of claim 21, wherein the AEF dose cup is located in an overscan region in relationship to the area of the workpiece scanned by the ribbon-like ion beam. 25. The system of claim 21, wherein the plane of the final energy bend in the ion beam is orthogonal to the plane of the ribbon-like ion beam. 26. The system of claim 21, wherein the AEF dose cup is located within the AEF system that is located in a chamber region upstream of the end station, wherein a pressure is reduced by a pump below a pressure of the end station. 27. The system of claim 21, further comprising a dose compensation control system, wherein the AEF dose cup measurement is used to control the scan velocity of the workpiece across the ion beam. 28. The system of claim 27, further comprising pressure compensation to correct the AEF dose cup measurements, the pressure compensation comprising:a pressure sensor operable to measure a pressure associated with the implantation system in the AEF system located external to the end station chamber, the sensor having an output connected to the compensation control system to correct the scan velocity based on the pressure measured;one of a compensation circuit, and a compensation software routine adapted to determine a pressure compensation factor as a function of the measured pressure and the measured ion beam current; anda scan motion control system operable to control a scan velocity of the workpiece across the ion beam based on the pressure measured and the pressure compensation factor. 29. The system of claim 27, wherein an AEF system is located in an AEF chamber region external to the end station chamber, and wherein the pressure within the AEF chamber is further reduced by a pump below the pressure of the end station chamber downstream from the AEF chamber to further reduce the effect of outgassing and pressure on the AEF cup. 30. The system of claim 21, wherein readings from a dose cup near the workpiece are compared to those of the AEF cup during an implant to deduce the charge exchange rate difference between the two positions, thereby enabling a determination of the number of neutral particles produced over the corresponding path length. 31. The system of claim 21, wherein the ion current measured at the AEF dose cup is proportional to the current going to the workpiece. 32. The system of claim 21, wherein the ion current implanted at the workpiece is determined during implant to be proportional to the current measured in the AEF dose cup by a scaling factor Cp according to the relationship:Iimplanted=IAEF*Cp. 33. The system of claim 32, wherein Cp is calculated based on readings of the AEF cup and an End Station cup to determine the fraction of charge exchange affecting the AEF cup and to compensate the readings for pressure changes. 34. The system of claim 21, wherein the ion beam is a scanned ion beam. 35. The system of claim 21, wherein the ion beam is a continuous ribbon-like ion beam. 36. The system of claim 21, wherein the AEF dose cup is located at a position wherein measurements of the ion current associated with final energy of the beam may be made before the beam has subsequently exchanged a greater portion of the ions of the beam on the path toward the workpiece. 37. The system of claim 21, wherein the AEF dose cup is located at a position wherein measurements of the ion current associated with final energy of the beam may be made before the beam has subsequently exchanged a significant portion of the ions of the beam on the path toward the workpiece. 38. A method of dynamically compensating for pressure and ion source variations using an AEF dose cup located near a final energy bend upstream of an end station, the AEF dose cup located external to an end station chamber in an ion implantation system, comprising:providing a workpiece within the end station chamber having a profiler cup at therein near the plane of a workpiece of the ion implantation system;calibrating the AEF dose cup during an implant set-up process to establish an ion current proportionality constant relative to the profile cup;assuming an initial scan velocity of the workpiece past the ion beam;implanting a region of the workpiece with an ion beam using the ion implantation system and the established ion current proportionality constant while measuring ion beam current at the AEF dose cup in the ion implantation system;measuring the ion current associated with the implanted workpiece; anddetermining a scan velocity compensation according to the initial scan velocity, the measured ion beam current at the AEF dose cup, the ion current proportionality constant, and a desired dose level.