Electron source

What is claimed is: 1. An electron source comprising: a silicon substrate having a top surface; at least one field emitter formed directly on the top surface of the silicon substrate, wherein the field emitter comprises a pyramid or a rounded whisker; and a boron layer hermetically disposed on the field emitter, wherein the boron layer is greater than 90% boron, and wherein the boron layer covers the field emitter from the silicon substrate to a tip of the field emitter. 2. The electron source of claim 1 , wherein the boron layer comprises less than 10% oxygen near an interface between the boron layer and the silicon substrate. 3. The electron source of claim 1 , wherein the tip of the field emitter has a lateral dimension less than 100 nm. 4. The electron source of claim 3 , wherein the tip of the field emitter has a lateral dimension greater than 20 nm. 5. The electron source of claim 1 , wherein the tip of the field emitter has a diameter less than 100 nm. 6. The electron source of claim 1 , further comprising an electrode held at a positive voltage of at least 500 V relative to the field emitter at a distance of at least 50 μm from the field emitter. 7. The electron source of claim 6 , wherein the field emitter is configured to operate in a reverse bias mode in which a depletion layer is generated by an electric field at a surface of the field emitter. 8. The electron source of claim 1 , further comprising an electrode held at a positive voltage of less than 500 V relative to the field emitter at a distance of 2 μm or less from an apex of the field emitter. 9. The electron source of claim 8 , wherein the field emitter is configured to operate in a reverse bias mode in which a depletion layer is generated by an electric field at an emitter surface of the field emitter. 10. The electron source of claim 1 , wherein the field emitter is p-type doped with a doping level less than about 10 19 cm −3 . 11. The electron source of claim 1 , wherein the field emitter is p-type doped with a doping level less than about 10 14 cm −3 . 12. The electron source of claim 11 , further comprising a light source that illuminates the field emitter, wherein the light source comprises one of a laser diode and a light emitting diode and wherein the light source is configured to maintain a desired emission current from the field emitter. 13. The electron source of claim 1 , wherein the field emitter is n-type doped with a doping level between about 10 16 cm −3 and about 10 19 cm −3 . 14. The electron source of claim 1 , wherein the boron layer has a thickness from 2 nm to 6 nm. 15. The electron source of claim 1 , further comprising: a dielectric layer disposed on the top surface adjacent to the field emitter; and a conductive gate disposed on the dielectric layer opposite of the substrate, wherein the thickness of the dielectric layer is approximately equal to or less than a height of the field emitter. 16. The electron source of claim 1 , further comprising a plurality of the field emitters arranged in a two-dimensional periodic pattern. 17. The electron source of claim 16 , further comprising: a dielectric layer disposed on the top surface surrounding the plurality of field emitters; and a conductive gate disposed on the dielectric layer opposite of the substrate, wherein the thickness of the dielectric layer is approximately equal to or less than a height of a field emitter. 18. A device comprising: an electron source for generating a primary electron beam that is directed toward a sample, wherein the electron source comprises: a silicon substrate having a top surface; at least one field emitter formed directly on the top surface of the silicon substrate, wherein the field emitter comprises a pyramid or a rounded whisker; and a boron layer disposed on the field emitter, wherein the boron layer is greater than 90% boron, and wherein the boron layer covers the field emitter from the silicon substrate to a tip of the field emitter; and electron optics. 19. The device of claim 18 , wherein the device is a scanning electron microscope (SEM), wherein the electron optics are configured to de-magnify and focus the primary electron beam onto the sample, and wherein the device further comprises a detector for detecting at least one of back-scattered electrons and secondary electrons from the sample. 20. The device of claim 18 , wherein the electron source further comprises: a dielectric layer disposed on the top surface adjacent to the field emitter; and a conductive gate disposed on the dielectric layer opposite of the substrate, wherein the thickness of the dielectric layer is approximately equal to or less than a height of the field emitter. 21. The device of claim 18 , wherein the electron source further comprises a light source configured to control the current of the primary electron beam. 22. The device of claim 18 , wherein the device is an electron-beam lithography system, wherein the electron optics are configured to de-magnify and focus the primary electron beam onto the target, and wherein the device further comprises a modulator for modulating the intensity of the electron beam. 23. The device of claim 18 , wherein the device is an X-ray source, and wherein the electron optics are configured to direct the primary electron beam to the anode.