Patent Number: 
Section: claims

1. A method for generating an electron beam, comprising the steps of: generating an electron beam using a field emission emitter;  passing a first passed portion of said electron beam through a screening aperture defined by a screening element, said screening element collecting a first collected portion of said electron beam, wherein the first passed portion comprises only a portion of the electron beam comprising spatially correlated electrons;  passing a second passed portion of said electron beam through a beam-limiting aperture defined by a beam-limiting element, wherein said screening element is located between said emitter and said beam-limiting aperture and said beam-limiting element collects a second collected portion of said first passed electron beam portion incident thereon; and  measuring the beam current at said beam-limiting element. 2. A method as recited in  claim 1  wherein said screening aperture transmits only a portion of the electron beam within an emission half cone angle xcex1 given approximately by  claim 1 where T is the temperature of the tip of said emitter, k is Boltzmann""s constant, and "PHgr" is the electron energy. 3. An inspection method using a field emission electron gun, comprising the steps of: generating an electron beam using a field emission emitter;  passing a first passed portion of said electron beam through a screening aperture defined by a screening element, said screening element collecting a first collected portion of said electron beam, wherein the first passed portion comprises only a portion of the electron beam comprising spatially correlated electrons;  passing a second passed portion of said electron beam through a beam-limiting aperture defined by a beam-limiting element, wherein said screening element is located between said emitter and said beam-limiting aperture and said beam-limiting element collects a second collected portion of said first passed electron beam portion incident thereon;  measuring the beam current at said beam-limiting element to generate beam current data;  directing a final portion of said electron beam onto a surface of a target; and  measuring the interaction of said final portion of the electron beam and said target to generate corrected target data by correcting for the effect of field emission noise using said beam current data. 4. A method as recited in  claim 3  wherein said screening aperture transmits only a portion of the electron beam within an emission half cone angle xcex1 given approximately by  claim 3 where T is the temperature of the tip of said emitter, k is Boltzmann""s constant, and "PHgr" is the electron energy. 5. A method as recited in  claim 3  wherein said step of measuring the interaction of said electron beam and said target includes measuring the emission of secondary electrons from said target. claim 3 6. A method as recited in  claim 3  wherein said step of directing said final portion of the electron beam onto the surface of the target includes focusing said electron beam onto the surface of said target. claim 3 7. A method as recited in  claim 3  further comprising the step of deflecting said final portion of the eletron beam so as to move said beam along the surface of said target. claim 3 8. An apparatus for generating an electron beam, comprising: a field emission emitter for generating an electron beam;  a screening element in the path of said electron beam, the screening element defining a screening aperture in the path of the beam for allowing a first portion of the electron beam to pass therethrough, said screening element is adapted to collect a first collected portion of said electron beam, wherein said first passed portion comprises only a portion of the electron beam comprising spatially correlated electrons;  a beam-limiting element in the path of said electron beam, said beam-limiting element defining a beam-limiting aperture for allowing a second passed portion of said electron beam to pass therethrough, wherein said screening element is located between said emitter and said beam-limiting aperture, said beam-limiting element is adapted to collect a second collected portion of said first passed electron beam portion incident thereon; and  means for measuring the beam current at said beam-limiting element. 9. An apparatus as recited in  claim 8  wherein said screening aperture transmits only a portion of the electron beam within an emission half cone angle xcex1 given approximately by  claim 8 where T is the temperature of the tip of said emitter, k is Boltzmann""s constant, and "PHgr" is the electron energy. 10. An apparatus for inspecting a target using a field emission electron gun, comprising: a field emission emitter for generating an electron beam;  a screening element, defining a screening aperture, in the path of said electron beam, the screening aperture for allowing a first portion of the electron beam to pass therethrough, said screening element is adapted to collect a first collected portion of said electron beam, wherein the first passed portion comprises only a portion of the electron beam comprising spatially correlated electrons;  a beam-limiting element in the path of said electron beam, said beam-limiting element defining a beam-limiting aperture for allowing a second passed portion of said electron beam to pass therethrough, wherein said screening element is located between said emitter and said beam-limiting aperture, said beam-limiting element is adapted to collect a second collected portion of said first passed electron beam portion incident thereon;  means for measuring the beam current at said beam-limiting element;  means for directing a final portion of said electron beam onto a surface of a target;  a detector for measuring the interaction of said final portion of the electron beam and said target to generate corrected target data; and  processor means for generating corrected target data by correcting for the effect of field emission noise using said beam current data. 11. An apparatus as recited in  claim 10  wherein said screening aperture transmits only a portion of the electron beam within an emission half cone angle xcex1 given approximately by  claim 10 where T is the temperature of the tip of said emitter, k is Boltzmann""s constant, and "PHgr" is the electron energy. 12. An apparatus as recited in  claim 10  wherein said detector is an electron detector for measuring the emission of secondary electrons from said target. claim 10 13. An apparatus as recited in  claim 10  wherein said means for directing said final portion of the electron beam onto the surface of the target includes an electron-optic lens for focusing said electron beam onto the surface of said target. claim 10 14. An apparatus as recited in  claim 10  further comprising means for deflecting said final portion of the electron beam so as to move said beam along the surface of said target. claim 10 15. A method as recited in  claim 1 , wherein the first collected electron beam portion collected by said screening element is substantially greater than the second collected electron beam portion collected by said beam-limiting element. claim 1 16. A method as recited in  claim 3 , wherein the first collected electron beam portion collected by said screening element is substantially greater than the second collected electron beam portion collected by said beam-limiting element. claim 3 17. An apparatus as recited in  claim 8 , wherein the first collected electron beam portion collected by said screening element is substantially greater than the second collected electron beam portion collected by said beam-limiting element. claim 8 18. An apparatus as recited in  claim 10 , wherein the first collected electron beam portion collected by said screening element is substantially greater than the second collected electron beam portion collected by said beam-limiting element. claim 10