Patent Number: 
Section: claims

1. An ion implanter comprising: an ion source for generating an ion beam;  at least one magnet disposed in the path of the ion beam for deflecting ions in the ion beam, said at least one magnet comprising first and second polepieces spaced apart to define a magnet gap through which the ion beam is transported;  an electron source disposed on or in proximity to at least one of said polepieces for producing low energy electrons in the magnet gap; and  a target site downstream of said at least one magnet for supporting a target for ion implantation, wherein the ion beam is delivered to said target site. 2. An ion implanter as defined in  claim 1 , wherein the target is a semiconductor wafer. claim 1 3. An ion implanter as defined in  claim 1 , wherein said at least one magnet comprises one magnet. claim 1 4. An ion implanter as defined in  claim 1 , wherein said at lest one magnet comprises a plurality of magnets. claim 1 5. An ion implanter as defined in  claim 1 , wherein the ion beam comprises a ribbon ion beam having a ribbon beam width and wherein said electron source produces low energy electrons across the ribbon beam width. claim 1 6. An ion implanter as defined in  claim 1 , wherein the ion beam is scanned so as to produce an effective scan width and wherein said electron source produces low energy electrons across the scan width. claim 1 7. An ion implanter as defined in  claim 1 , wherein said electron source comprises one or more linear electron sources disposed perpendicular to a direction of transport of the ion beam. claim 1 8. An ion implanter as defined in  claim 1 , wherein said electron source comprises a one-dimensional array of electron sources. claim 1 9. An ion implanter as defined in  claim 1 , wherein said electron source comprises a two-dimensional array of electron sources. claim 1 10. An ion implanter as defined in  claim 1 , wherein said electron source comprises an area electron source. claim 1 11. An ion implanter as defined in  claim 1 , wherein said electron source comprises an array of field emitters mounted to at least one of said polepieces and facing the magnet gap. claim 1 12. An ion implanter as defined in  claim 1 , wherein said electron source comprises one or more electron-emitting wires disposed in proximity to at least one of said polepieces and perpendicular to a direction of transport of the ion beam. claim 1 13. An ion implanter as defined in  claim 12 , wherein said magnet further comprises a polepiece liner and wherein said one or more electron-emitting wires are recessed in the polepiece liner. claim 12 14. An ion implanter as defined in  claim 13 , wherein said one or more electron-emitting wires comprise tungsten wires and wherein said polepiece liner comprises graphite. claim 13 15. An ion implanter as defined in  claim 12 , wherein said one or more electron-emitting wires are recessed in at least one of said polepieces. claim 12 16. An ion implanter as defined in  claim 12 , wherein said electron source further comprises an insulator disposed behind each of said one or more electron-emitting wires for reflecting electrons toward the ion beam. claim 12 17. An ion implanter as defined in  claim 12 , wherein said electron source further comprises an electrically isolated conductor disposed behind each of said one or more electron-emitting wires for reflecting electrons toward the ion beam. claim 12 18. An ion implanter as defined in  claim 17 , further comprising a bias power supply connected to said conductor for controlling the efficiency of electron reflection. claim 17 19. An ion implanter as defined in  claim 1 , wherein said electron source is mounted on at least one of said polepieces in the magnet gap. claim 1 20. An ion implanter as defined in  claim 1 , wherein said electron source is located between said first and second polepieces. claim 1 21. An ion implanter as defined in  claim 1 , wherein said electron source is recessed in at least one of said polepieces. claim 1 22. A method for transporting an ion beam through a magnet, comprising: directing the ion beam through a magnet gap between first and second polepieces of the magnet; and  supplying low energy electrons to the ion beam being transported through the magnet gap between the first and second polepieces of the magnet by an electron source disposed on or in proximity to at least one of the first and second polepieces. 23. A method as defined in  claim 22 , further comprising the step of transporting the ion beam from the magnet to a target at a target site. claim 22 24. A method as defined in  claim 22 , wherein the step of supplying low energy electrons comprises supplying electrons from one or more electron sources disposed perpendicular to a direction or transport of the ion beam. claim 22 25. A method as defined in  claim 22 , wherein the step of supplying low energy electrons comprises supplying electrons from one or more electron-emitting wires disposed in proximity to at least one of the polepieces. claim 22 26. A magnet assembly for operation with an ion beam, comprising: a magnet disposed in the path of the ion beam, said magnet comprising first and second polepieces spaced apart to define a magnet gap through which the ion beam is transported; and  one or more electron sources disposed on or in proximity to at least one of said polepieces for producing low energy electrons in the magnet gap.