Patent Number: 060382791
Section: claims

1. An X-ray generating device for use with an X-ray projection optical system having X-ray mirrors for projecting an image of an irradiated first object to a second object, said device comprising: a laser source for generating a laser beam;  a target having a plurality of points for receiving the laser beam, the plurality of points forming a plurality of high temperature plasma portions, each of which generates an X-ray beam; and  an illuminating optical system for irradiating an object with the X-ray beams from the high temperature plasma portions substantially under Kohler's illumination condition.  a laser source for generating a laser beam;  an aperture, having a variable shape, for receiving the laser beam and for defining a shape of a secondary light source;  a target for receiving the laser beam and for generating X-rays from portions of high temperature plasma on the target; and  an illuminating optical system for irradiating an object with the X-ray beams from the high temperature plasma portions substantially under Kohler's illumination condition.  (i) an X-ray generating device comprising:  (ii) irradiating means for irradiating a first object with the plurality of X-ray beams generated by said X-ray generating device; and  (iii) an X-ray projection optical system having X-ray mirrors for projecting an image of the irradiated first object to a second object.  (i) an X-ray generating device comprising:  (ii) irradiating means for irradiating an object with the X-rays generated by said X-ray generating device; and  (iii) an X-ray projection optical system having X-ray mirrors for projecting an image of the irradiated first object to a second object.  generating at least one laser beam from at least one laser source;  providing a target having a plurality of points for receiving the at least one laser beam;  forming, from the plurality of points, a plurality of high temperature plasma portions;  generating X-ray beams from each of the high temperature plasma portions; and  irradiating an object with the X-ray beams from the high temperature plasma portions substantially under Kohler's illumination condition.  generating a laser beam from a laser source;  providing an aperture, having a variable shape, for receiving the laser beam and for defining a shape of a secondary light source;  providing a target for receiving the laser beam;  generating X-rays from portions of high temperature plasma on the target; and  irradiating an object with the X-ray beams from the high temperature plasma portions substantially under Kohler's illumination condition.  generating at least one laser beam from at least one laser source;  providing a target having a plurality of points of high temperature plasma for receiving the at least one laser beam;  forming, from the plurality of points, a plurality of high temperature plasma portions;  generating X-ray beams from each of the high temperature plasma portions;  irradiating a mask with the X-rays generated from the high temperature plasma portions; and  projecting an image of a pattern carried by the irradiated mask onto a semiconductor wafer to produce a semiconductor device.  generating a laser beam from a laser source;  providing an aperture, having a variable shape, for receiving the laser beam and for defining a shape of a secondary light source;  providing a target for receiving the laser beam;  generating X-rays from portions of high temperature plasma on the target;  irradiating a mask with the X-rays generated from the high temperature plasma portions; and  projecting an image of a pattern carried by the irradiated mask onto a semiconductor wafer to produce a semiconductor device.  laser source means for generating at least one laser beam;  a target having a plurality of points for receiving the at least one laser beam, the plurality of points forming a plurality of high temperature plasma portions simultaneously, each of which generates an X-ray beam; and  an X-ray projection optical system having X-ray mirrors for projecting an image of an irradiated first object to a second object by the X-ray beams generated by the plurality of high temperature plasma portions, wherein the X-ray beams from the plurality of high temperature plasma portions are irradiated on the first object simultaneously. 2. An X-ray generating device according to claim 1, wherein the plurality of points are non-uniformly distributed. 3. An X-ray generating device according to claim 1, wherein the plurality of points are distributed in a distribution pattern such that the distribution density is lower in a central region than in a peripherals region. 4. An X-ray generating device for use with an X-ray projection optical system having X-ray mirrors for projecting an image of an irradiated first object to a second object, said device comprising: 5. An X-ray generating device according to claim 4, wherein said variable aperture controls at least one of the configuration, size, position and number of the portions of the laser plasma on the target. 6. An X-ray projection apparatus comprising: 7. An X-ray irradiating apparatus according to claim 6, wherein the plurality of points are non-uniformly distributed. 8. An X-ray irradiating apparatus according to claim 6, wherein the plurality of points are distributed in a distribution pattern such that the distribution density is lower in a central region than in a peripheral region. 9. An X-ray irradiating apparatus according to claim 6, wherein said irradiating means irradiates the object substantially under Kohler's illumination conditions. 10. An X-ray irradiating apparatus according to claim 6, further comprising optical means for projecting an image of a pattern carried by the irradiated mask onto a wafer. 11. An X-ray irradiating apparatus according to claim 10, wherein said optical means comprises a demagnifying image forming optical system. 12. An X-ray projection apparatus comprising: 13. An X-ray irradiating apparatus according to claim 12, wherein said variable aperture controls at least one of the configuration, size, position and number of the portions of the laser plasma on the target. 14. An X-ray irradiating apparatus according to claim 12, wherein said irradiating means irradiates the object substantially under Kohler's illumination conditions. 15. An X-ray irradiating apparatus according to claim 12, further comprising optical means for projecting an image of a pattern carried by the irradiated mask onto a wafer. 16. An X-ray irradiating apparatus according to claim 15, wherein said optical means comprises a demagnifying image forming optical system. 17. An X-ray generating method for use with an X-ray projection optical system having X-ray mirrors for projecting an image of an irradiated first object to a second object, said method comprising: 18. An X-ray generating method according to claim 17, wherein the plurality of points are non-uniformly distributed. 19. An X-ray generating method according to claim 17, wherein the plurality of points are distributed in a distribution pattern such that the distribution density is lower in central region than in a peripheral region. 20. An X-ray generating method according to claim 17, further comprising deflecting the at least one laser beam to the plurality of the points. 21. An X-ray generating method according to claim 17, further comprising effecting incoherent illumination of an object with the X-rays from the portions. 22. An X-ray generating method for use with an X-ray projection optical system having X-ray mirrors for projecting an image of an irradiated first object to a second object, said method comprising: 23. An X-ray generating method according to claim 22, further comprising applying the secondary laser beam to the target in a time series manner. 24. An X-ray generating method according to claim 22, further comprising controlling, using the variable aperture, at least one of the configuration, size, position and number of the portions of the laser plasma on the target. 25. An X-ray generating method according to claim 22, further comprising deflecting the at least one laser beam to the plurality of the points. 26. An X-ray generating method according to claim 22, further comprising varying the form of the portions by varying the shape of the variable aperture. 27. An X-ray generating method according to claim 26, further comprising effecting incoherent illumination of an object with X-rays from the portions. 28. A method of producing a semiconductor device, said method comprising the steps of: 29. A semiconductor device production method according to claim 28, wherein the plurality of points are non-uniformly distributed. 30. A semiconductor device production method according to claim 28, wherein the plurality of points are distributed in a distribution pattern such that the distribution density is lower in a central region than in a peripheral region. 31. A semiconductor device production method according to claim 28, further comprising deflecting the at least one laser beam to the plurality of points. 32. A semiconductor device production method according to claim 28, further comprising effecting incoherent illumination of the mask with the X-rays from the portions. 33. A semiconductor device production method according to claim 28, wherein said irradiating step comprises focusing the X-rays from the points onto the mask so as to effect Kohler's illumination of the mask. 34. A semiconductor device production method according to claim 28, wherein said irradiating step comprises causing the X-rays from the points to impinge on the mask at different angles. 35. A semiconductor device production method according to claim 34, further comprising changing the angular distribution of the X-rays, impinging on the mask. 36. A method of producing a semiconductor device, said method comprising the steps of: 37. A semiconductor device production method according to claim 36, further comprising applying the laser beam to the target in a time series manner. 38. A semiconductor device production method according to claim 36, further comprising controlling, using the variable aperture, at least one of the configuration, size, position and number of the portions of the laser plasma, on the target. 39. A semiconductor device production method according to claim 36, further comprising deflecting the at least one laser beam to the plurality of points. 40. A semiconductor device production method according to claim 36, further comprising varying the form of the portions by varying the shape of the variable aperture. 41. A semiconductor device production method according to claim 40, further comprising effecting incoherent illumination of the mask with X-rays from the portions. 42. A semiconductor device production method according to claim 36, wherein said irradiating step comprises focusing the X-rays from the points onto the mask so as to effect Kohler's illumination of the mask. 43. A semiconductor device production method according to claim 36, wherein said irradiating step comprises causing the X-rays from the points to impinge on the mask at different angles. 44. A semiconductor device production method according to claim 36, further comprising changing the angular distribution of the X-rays impinging on the mask. 45. An X-ray exposure apparatus comprising: