Patent Number: 
Section: claims

1. An electron beam system, comprising:an electron gun for generating an electron beam;an electron beam column;a deflector for deflecting the electron beam;an anti-fogging baffle arrangement having a main baffle portion having a center opening allowing the electron beam to pass and positioned to collect scattered electrons from a workpiece surface and an inner baffle portion also having a center opening allowing the electron beam to pass and positioned above the main baffle portion;at least one bias voltage source connected to the inner baffle portion; andan electrical lead connected to the main baffle portion, wherein the main baffle portion and the inner baffle portion are electrically isolated from one another. 2. The electron beam system of claim 1, wherein the main baffle portion is electrically coupled to a support plate. 3. An anti-fogging baffle arrangement, comprising:a main baffle portion electrically isolated and positioned to collect electrons scattered from a workpiece surface and an inner baffle portion having a center opening allowing an electron beam to pass and positioned above the main baffle portion; anda lead for providing a signal indicating an amount of electrons collected by the main baffle portion. 4. The anti-fogging baffle arrangement of claim 3, further comprising an inner baffle portion having a center opening and positioned above the main baffle portion. 5. The anti-fogging baffle arrangement of claim 3, further comprising a negative bias source connected to the inner baffle portion, wherein the negative bias source is configured to negatively bias the inner baffle portion to repel scattered electrons. 6. The anti-fogging baffle arrangement of claim 3, further comprising a positive bias source connected to the main baffle portion, wherein the positive bias source is configured to positively bias the main baffle portion to attract scattered electrons. 7. The anti-fogging baffle arrangement of claim 5, further comprising a positive bias source connected to the main baffle portion. 8. A method for measuring an amount of electrons scattered from a workpiece surface, comprising:generating an electron beam in a beam tube;deflecting the electron beam onto the workpiece surface causing the production of scattered electrons;shielding a surface of the beam tube from scattered electrons with an anti-fogging baffle arrangement;collecting scattered electrons using the anti-fogging baffle arrangement;generating a current signal by electrically isolating a portion of the scattered electrons collected using the anti-fogging baffle arrangement; andgenerating an image of at least some portion of the workpiece surface using the current signal. 9. The method of claim 8, further comprising applying a bias voltage to at least a portion of the anti-fogging baffle arrangement. 10. The method of claim 9, wherein the bias voltage is applied in a manner designed to enhance scattered electron collection and to prevent electrons from traveling through the anti-fogging baffle arrangement and up the beam tube. 11. The method of claim 8, further comprising analyzing the image to detect a position of marks formed on the workpiece surface. 12. The method of claim 8, further comprising analyzing the image to inspect fiduciary marks to ensure that the electron beam is striking the workpiece surface in a desired location. 13. The method of claim 8, further comprising analyzing the image to determine if different portions of the workpiece surface have a same focus in the image. 14. The method of claim 9, wherein applying a bias voltage comprises applying a negative bias between about −5 and about −50 volts. 15. The method of claim 9, wherein applying a bias voltage comprises applying a positive bias between about 5 and about 50 volts. 16. An electron beam system, comprising:an electron gun for generating an electron beam;an electron beam column;a deflector for deflecting the electron beam;an anti-fogging baffle arrangement having a main baffle portion having a center opening allowing the electron beam to pass and positioned to collect scattered electrons from a workpiece surface and an inner baffle portion also having a center opening allowing the electron beam to pass and positioned above the main baffle portion; andat least one bias voltage source connected to the anti-fogging baffle arrangement, wherein the at least one bias voltage source provides a negative bias voltage to the anti-fogging baffle arrangement to prevent the scattered electrons from traveling up the electron beam column. 17. The electron beam system of claim 16, wherein the at least one bias voltage source provides a positive bias voltage to the main baffle portion to attract scattered electrons. 18. An electron beam system, comprising:an electron gun for generating an electron beaman electron beam column;a deflector for deflecting the electron beam;an anti-fogging baffle arrangement having a main baffle portion having a center opening allowing the electron beam to pass and positioned to collect scattered electrons from a workpiece surface and an inner baffle portion also having a center opening allowing the electron beam to pass and positioned above the main baffle portion; andat least one bias voltage source connected to the anti-fogging baffle arrangement, wherein the at least one bias voltage source provides a positive bias voltage to the main baffle portion to attract scattered electrons. 19. The electron beam system of claim 18, wherein the anti-fogging baffle arrangement includes a lead, the at least one bias voltage source is part of a processing unit electrically connected to the lead, wherein the processing unit is configured to generate an image of at least some portion of the workpiece surface using the current signal. 20. The electron beam system of claim 19, wherein the processing unit is configured to utilize image processing algorithms to analyze a generated image to detect a position of marks formed on the workpiece surface.