Patent Number: 062884018
Section: claims

1. A source to emit a beam of charged particles, said source comprising: a charged particle emitter;  an extraction electrode spaced-apart from said emitter and having an aperture, with said aperture being in superimposition with said emitter 1 and having a center, said extraction electrode defining an optical axis passing through said center; and  a centering electrode disposed between said extraction electrode and said emitter, said centering electrode having an orifice lying in said optical axis.  directing said charged particle beam over a path defined by an extraction field produced between said emitter and said extraction electrode;  aligning said path with said optical axis by providing, between said emitter and said extraction electrode, an electrostatic deflection field.  applying a first voltage to said emitter; and  applying a second voltage to said extraction electrode;  wherein said extraction field is the difference between said first voltage and said second voltage.  applying a first centering voltage on one of said plurality of centering electrode elements disposed on a first side of said optical axis; and  applying a second centering voltage on another of said plurality of centering electrode elements disposed on a second side of said optical axis, with said second side being opposite said first side.  applying a first centering voltage on said first electrode element;  applying a second centering voltage on said second centering electrode element;  applying a third centering voltage on said third centering electrode element; and  applying a fourth centering voltage on said fourth centering electrode element, with said first, second, third and fourth electrode elements being complanar.  providing an additional electrostatic deflection field near said optical axis, with said electrostatic deflection field deflecting said charged particle beam along a first direction and said additional electrostatic deflection field deflecting said charged particle beam along a second direction, opposite to said first direction.  a charged particle emitter; and  an electrode system spaced-apart from said emitter to extract said beam of charged particles from said emitter to travel toward said electrode system, said electrode system defining an aperture in superimposition with said emitter and having a plurality of electrode segments to produce a deflection field between said electrode system and said emitter to guide said beam of charged particles through said aperture. 2. The source of claim 1 wherein said orifice has a cross-sectional area associated therewith that is substantially greater than a cross-sectional area of said aperture and superimposes a portion of said extraction electrode, with said portion defining an extraction region, with said orifice being radially and symmetrically disposed about a point, with said point lying is said optical axis. 3. The source of claim 1, wherein said centering electrode includes a plurality of spaced-apart electrode elements disposed adjacent to said extraction electrode with an insulating layer being disposed between said extraction electrode and said electrode elements. 4. The source of claim 1, wherein said emitter includes a filament having a tip, with said filament being coupled to a first source of voltage and said extraction electrode being connected to a second source of voltage to produce an electric field proximate to said tip and direct said charged particles along a path toward said extraction electrode and said centering electrode is connected to third and fourth voltage sources to align said path, proximate to said extraction electrode, with said optical axis. 5. The source of claim 1, wherein said emitter includes a filament having a tip, with said filament coupled to a first source of voltage and said centering electrode includes a pair of spaced apart electrode elements, with said extraction electrode being connected to a second source of voltage to produce an electric field proximate to said tip to direct said charged particles along a path toward said extraction electrode and each electrode element of said pair being connected to a voltage supply having a polarity associated therewith that is opposite to the polarity of the voltage supply associated with the remaining electrode element of said pair. 6. The source of claim 1, wherein said emitter is selected from the group consisting essentially of a Schottky emitter and a cold-field emitter. 7. The source of claim 1, wherein said centering electrode includes a first set of four electrode elements disposed between said extraction electrode and said emitter, and a second set of four centering electrode elements disposed between said first set of four electrode elements and said emitter, with a first insulating layer being disposed between said first set of four electrode elements and said extraction electrode and a second insulating layer being disposed between said first and second sets of four electrode elements. 8. The source of claim 7, wherein said emitter includes a filament having a tip, with said filament being coupled to a first source of voltage and said extraction electrode being connected to a second source of voltage to produce an electric field proximate to said tip and direct said charged particles along a path toward said aperture, with each of said electrode elements of said first and second sets of four electrode elements being connected to a differing voltage supply to align said path with said optical axis. 9. A method of aligning a charged particle beam, produced by an emitter, with an optical axis defined by an extraction electrode, said method comprising: 10. The method of claim 9, wherein directing said charged particle beam further includes: 11. The method of claim 9 further including providing a centering electrode having a plurality of centering electrode elements defining an orifice disposed in said optical axis, wherein directing said charged particle beam further comprises: 12. The method of claim 9 further including providing a centering electrode having a first, second, third and fourth centering electrode elements, defining an orifice disposed in said optical axis, with said first electrode element being disposed opposite to said second electrode element and said third electrode element being disposed opposite to said fourth electrode element, wherein directing said charged particle beam further comprises: 13. The method of claim 9 wherein said extraction electrode includes an aperture having a center and aligning said path with said optical axis includes providing a deflection field having a magnitude associated therewith that is asymmetrically distributed about said center to direct said charged particle beam through said aperture. 14. The method of claim 9 further including providing a second electrostatic deflection field near said optical axis, wherein said second electrostatic deflection field deflects said charged particle beam to travel approximately parallel to said optical axis. 15. The method of claim 9, further comprising: 16. A source to emit a beam of charged particles, said source comprising: 17. The source as recited in claim 16 wherein said plurality of electrode elements includes an extraction electrode defining said aperture and a centering electrode having a plurality of electrode segments, said centering electrode being disposed between said extraction electrode and said emitter and having an orifice centered about said optical axis, with a cross-sectional area of said orifice being substantially greater than a cross-sectional area of said aperture and superimposing a portion of said extraction electrode. 18. The source as recited in claim 16 wherein said electrode assembly includes an extraction electrode defining said aperture and a centering electrode defined by said plurality of electrode elements, with said plurality of electrode elements being disposed adjacent to said extraction electrode with an insulating layer being disposed between said extraction electrode and said electrode elements. 19. The source as recited in claim 17 wherein said emitter includes a filament having a tip, with said filament being coupled to a first source of voltage and said centering electrode is defined by a plurality of spaced-apart electrode segments, with said extraction electrode being connected to a second source of voltage to produce an electric field proximate to said tip and direct said charged particles along a path toward said extraction electrode, with said plurality of spaced-apart electrode segments being connected to differing voltage supplies to provide said deflection field, with said deflection field having a magnitude associated therewith that is asymmetrically distributed about said optical axis. 20. The source as recited in claim 19 wherein said plurality of electrode segments are arranged in first and second sets of four electrode segments, with said first set being disposed between said extraction electrode and said emitter and said second set being disposed between said first set said emitter, with a first insulating layer being disposed between said first set of four electrode segments and said extraction electrode and a second insulating layer being disposed between said first and second sets of four electrode segments.