Patent Number: 
Section: claims

1. A lithographic exposure device for fabricating a microporous filter membrane, said microporous filter membrane not supported by a solid substrate, comprising:means for exposing a membrane substrate to a beam comprising at least one energetic particle, wherein said energetic particle has an energy level greater than about 10 keV;means for applying a high emissivity coating to said membrane substrate prior to exposing said membrane substrate to said beam;means for conveying said membrane substrate; anda mask positioned between said membrane substrate and at least one source of said at least one energetic particle, said beam comprising at least one particle transmitted through said mask. 2. The lithographic exposure device of claim 1, wherein said device fabricates a filter membrane comprising at least one pore. 3. The lithographic exposure device of claim 1, wherein said mask is substantially stationary. 4. The lithographic exposure device of claim 1, wherein said means for conveying said membrane substrate further comprises a clamp for securing said membrane substrate. 5. The lithographic exposure device of claim 1, wherein said means for conveying said membrane substrate advances said membrane substrate in a stepwise fashion, and wherein said membrane substrate is advanced about a length of said mask for every step. 6. The lithographic exposure device of claim 1, further comprising an etchant exposure system. 7. The lithographic exposure device of claim 1, further comprising a means for removing said high emissivity coating from said filter membrane substrate after said exposure. 8. A filter membrane produced with a device according to claim 1. 9. The lithographic exposure device of claim 1, wherein said energetic particle is selected from at least one of an ion, a photon, an electron, a neutral energetic atom and an energetic molecule. 10. The lithographic exposure device of claim 1, wherein said energetic particle comprises at least one of hydrogen or helium ions. 11. A lithographic exposure device for fabricating a microporous filter membrane, said microporous filter membrane not supported by a solid substrate, comprising:a radiation source directed at least partially on a membrane substrate, wherein said radiation source's emitted radiation comprises a beam of at least one energetic particle, wherein said energetic particle has an energy level greater than about 10 keV;a device for applying a high emissivity coating to a membrane substrate prior to exposure to said radiation source;a device for conveying said membrane substrate comprising at least one supply reel and at least one take-up reel; anda mask positioned between said membrane substrate and at least one source of said at least one energetic particle, said beam comprising at least one particle transmitted through said mask. 12. The lithographic exposure device of claim 11, wherein said mask is substantially stationary. 13. The lithographic exposure device of claim 11, wherein said device for conveying said membrane substrate further comprises a clamp for securing said membrane substrate. 14. The lithographic exposure device of claim 13, wherein said clamp is electrostatic. 15. The lithographic exposure device of claim 11, further comprising an etchant exposure system. 16. The lithographic exposure device of claim 11, further comprising a device for removing a high emissivity coating from said filter membrane substrate after said lithographic exposure. 17. A filter membrane produced with the device according to claim 11. 18. The lithographic exposure device of claim 11, wherein said energetic particle comprises helium ions. 19. The lithographic exposure device of claim 11, wherein said energetic particle comprises hydrogen ions. 20. A process for fabricating a microporous filter membrane, said microporous filter membrane not supported by a solid substrate, said process comprising the steps of:conveying a membrane substrate in a stepwise fashion adjacent a mask;applying a high emissivity coating to said membrane substrate;damaging said membrane substrate with at least one beam comprising at least one energetic particle emitted from at least one radiation source directed at least partially through said mask, wherein said energetic particle has an energy level greater than about 10 keV, and wherein said damaging occurs after said application of said high emissivity coating to said membrane substrate; andremoving said damaged membrane substrate with an etchant. 21. The process of claim 20, wherein said step of conveying said membrane substrate in a stepwise fashion advances said membrane substrate about a length of said mask for every step. 22. The process of claim 20, wherein said membrane substrate is substantially stationary for at least a portion of each step. 23. A filter membrane produced according to the process of claim 20. 24. The process of claim 20, wherein said high thermal emissivity coating is applied only to one side of said membrane substrate. 25. The process of claim 20, further comprising the step of removing said high emissivity coating from said membrane substrate after said damaging. 26. The process of claim 20, wherein said energetic particle comprises at least one of hydrogen or helium ions. 27. A process for fabricating a microporous filter membrane, said process comprising the steps of:applying an intermediate mask layer and a resist coating to a membrane substrate;applying a high emissivity coating to said membrane substrate;conveying said membrane substrate in a stepwise fashion adjacent a mask;exposing said resist coating with at least one beam comprising at least one energetic particle emitted from at least one radiation source directed at least partially through said mask, wherein said energetic particle has an energy level greater than about 10 keV, and wherein said exposure occurs after said application of said high emissivity coating to said membrane substrate;developing said resist coating;etching said resist coating's pattern through said intermediate mask layer; andetching said intermediate mask layer's pattern into said membrane substrate. 28. The process of claim 27, wherein said high thermal emissivity coating is applied only to one side of said membrane substrate. 29. The process of claim 27, further comprising the step of removing said high emissivity coating from said membrane substrate after said exposure. 30. The process of claim 27, wherein said energetic particle comprises at least one of hydrogen or helium ions.