Patent Number: 051538989
Section: claims

1. An X-ray exposure apparatus, comprising: a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays; and  a reflection reduction imaging system disposed between said mask stage and said wafer stage comprising a reflecting mirror arrangement comprising at least three, but not more than five, reflecting mirrors coated with multi-layer films for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays;  wherein at least one of the reflecting mirrors is provided with an aspherical reflecting surface.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays; and  a reflection reduction imaging system disposed between said mask stage and said wafer stage including a reflecting mirror arrangement containing at least one flat mirror and a plurality of non-flat mirrors, each of which mirrors are coated with multi-layer films, for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays; and  a reflection reduction imaging system disposed between said mask stage and said wafer stage including a reflecting mirror arrangement containing plural multi-layer film coated reflecting mirrors, at least one of which is provided with forced cooling means, for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays;  a reflection reduction imaging system disposed between said mask stage and said wafer stage including a reflecting mirror arrangement containing a plurality of reflecting mirrors coated with multi-layer films for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays; and  wherein helium gas flows through a space between at least two of said reflecting mirrors.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays;  means for forcingly cooling the mask; and  a reflection reduction imaging system disposed between said mask stage and said wafer stage including a reflecting mirror arrangement containing a plurality of reflecting mirrors coated with multi-layer films for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask;  a reflection reduction imaging system disposed between said mask stage and said wafer stage including a reflecting mirror arrangement containing a plurality of reflecting mirrors which are coated with multi-layer films, at least one of the plurality of reflecting mirrors having an aspherical reflecting surface, said reflection reduction imaging system for exposing the wafer to a reduced image of the mask pattern in a rectangular area; and  means for stepwisely moving said wafer stage to sequentially expose areas on the wafer having a configuration corresponding to the rectangular area.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays;  plural reflecting mirrors for reflecting X-rays, disposed between said mask stage and said wafer stage, to expose the wafer to a reduced image of the mask pattern; and  means for detecting a mark on said wafer stage in an enlarged scale using visible light coming from the wafer by way of said reflecting mirrors in a direction opposite to a direction of travel of the X-rays for exposing the wafer, whereby the mark can be detected substantially free from aberration.  a mask stage for vertically holding a mask having a pattern for circuit manufacturing;  a synchrotron orbital radiation source for producing energy rays for application of the rays to the mask;  a wafer stage for horizontally holding a wafer to be exposed to the pattern of the mask with the rays; and  reduction imaging means disposed between the mask and the wafer for exposing the wafer to a reduced image of the mask pattern, said imaging means comprising a plurality of reflecting mirrors, at least one of the reflecting mirrors having an aspherical reflecting surface and at least one of the reflecting mirrors being coated with a multi-layer film; and  means for sequentially moving said wafer stage for sequentially exposing plural exposure areas of the wafer to the reduced image of the mask pattern.  a first concave mirror having a multi-layer film reflecting surface; and  a second concave mirror having a multi-layer reflecting film for receiving X-rays from said first concave mirror, said second concave mirror having an opening eccentric with respect to an axis of the imaging system for allowing the X-rays to pass through said second concave mirror.  a first mirror having a concave reflecting surface for reflecting X-rays from an object;  a second mirror having a convex reflecting surface for receiving the X-rays from said first mirror and reflecting them;  a third mirror having a concave reflecting surface for receiving the X-rays from said second convex mirror and reflecting them to form an image of the object; and  wherein the reflecting surface of at least one of said first and third concave mirrors is aspherical, whereby an image formed by the X-rays involves minimized aberrations; and wherein the reflecting surface of at least one of said mirrors is provided with a multi-layer coating.  imaging means provided between the object and a plane on which the image thereof is produced for receiving and reflecting X-rays, said imaging means comprising a plurality of X-ray reflecting elements provided with multi-layer coatings; and  X-ray application means for applying the X-rays to the object inclinedly with respect to a surface of the object to cause the X-rays incident on the plane to be substantially parallel to a system axis of said imaging means.  an inlet port for receiving X-rays travelling substantially in a horizontal direction;  a mask holder for holding a mask substantially vertically for the mask to receive the X-rays through said inlet port;  a first mirror for receiving the X-rays coming from the mask and reflecting them in a substantially vertical direction;  a second mirror disposed above said first mirror having a bottom curved reflecting surface for receiving the X-rays from the first mirror and reflecting them;  a third mirror disposed below said first mirror having a top curved reflecting surface for receiving the X-rays coming from said second mirror and reflecting them;  a fourth mirror disposed between said first and second mirrors having a bottom curved reflecting surface for receiving the X-rays from said third mirror and reflecting them substantially vertically; and  a holder for holding the sensitive member substantially horizontally for the sensitive member to receive the X-rays from the fourth mirror.  a mask stage for holding a mask having a pattern for circuit manufacturing;  a wafer stage for holding a wafer to be exposed to the pattern of the mask with X-rays; and  a reflection reduction imaging system disposed between said mask stage and said wafer stage comprising reflecting mirrors coated with multi-layer films for receiving X-rays from the mask and directing them to the wafer to expose the wafer to a reduced image of the mask pattern with the X-rays;  wherein at least one of the reflecting mirrors is provided with an aspherical reflecting surface.  an original supporting stage for supporting an original;  a substrate supporting stage for supporting a substrate; and  a mirror assembly for projecting an image of a pattern of the original onto the substrate using X-rays, said mirror assembly comprising at least three mirrors each having curved reflecting surfaces and at least one of which has an aspherical reflection surface.  providing a mirror assembly including at least three mirrors each having curved reflecting surfaces and at least one of which has an aspherical mirror surface; and  projecting an image of a pattern of an original onto a substrate through the mirror assembly to transfer the pattern onto the substrate using X-rays.  an original holder for holding an original having a pattern;  a substrate holder for holding a substrate having plural areas;  a projection system for projecting the pattern of the original onto an area of the substrate in a reduced scale, said projection system comprising a plurality of reflecting mirrors, wherein at least one of said mirrors has an aspherical reflection surface; and  means for moving said substrate holder to sequentially transfer the pattern onto the areas of the substrate.  an original holder for holding an original having a pattern;  a substrate holder for holding a substrate having plural areas;  a projection system for projecting the pattern of the original onto an area of the substrate, said projection system comprising a plurality of reflecting mirrors, wherein at least one of said mirrors has an aspherical reflection surface; and  means for moving said substrate holder to sequentially transfer the pattern onto the areas of the substrate.  an original holder for holding an original having a pattern;  substrate holder for holding a substrate having plural areas;  a projection system for projecting the pattern of the original onto an area of the substrate in a reduced scale, said projection system comprising at least three curved reflection surface mirrors, wherein at least one of said mirrors has an aspherical reflection surface; and  means for moving said substrate holder to sequentially transfer the pattern onto the areas of the substrate.  holding an original having a pattern;  holding a substrate having plural areas with a substrate holder;  projecting the pattern of the original onto an area of the substrate in a reduced scale using a projection system having a plurality of reflecting mirrors, wherein at least one of the mirrors has an aspherical reflection surface; and  moving the substrate holder to sequentially transfer the pattern onto the areas of the substrate.  holding an original having a pattern;  holding a substrate having plural areas with a substrate holder;  projecting the pattern of the original onto an area of the substrate using a projection system having a plurality of reflecting mirrors, wherein at least one of the mirrors has an aspherical reflection surface; and  moving the substrate holder to sequentially transfer the pattern onto the areas of the substrate.  holding an original having a pattern;  holding a substrate having plural areas with a substrate holder;  projecting the pattern of the original onto an area of the substrate in a reduced scale using a projection system having at least three reflection surface mirrors, wherein at least one of the mirrors has an aspherical reflection surface; and  moving the substrate holder to sequentially transfer the pattern onto the areas of the substrate. 2. An apparatus according to claim 1, further including forced cooling means for cooling at least one of the reflecting mirrors. 3. An apparatus according to claim 1, wherein a space between at least two reflecting mirrors is filled with helium gas. 4. An X-ray exposure apparatus, comprising: 5. An apparatus according to claim 4, wherein at least one of the non-flat reflecting mirrors is provided with an aspherical reflecting surface. 6. An apparatus according to claim 4, further including cooling means for cooling at least one of the reflecting mirrors. 7. An apparatus according to claim 4, wherein a space between at least two reflecting mirrors is filled with helium gas. 8. An X-ray exposure apparatus, comprising: 9. An apparatus according to claim 8, wherein at least one of the reflecting mirrors is provided with an aspherical reflecting surface. 10. An apparatus according to claim 8, wherein at least two reflecting mirrors nearest the mask stage are provided with forced cooling means. 11. An apparatus according to claim 8, wherein helium gas flows in a space between at least two of the reflecting mirrors. 12. An X-ray exposure apparatus, comprising: 13. An apparatus according to claim 12, wherein at least one of the reflecting mirrors is provided with an aspherical reflecting surface. 14. An apparatus according to claim 12, further including cooling means for cooling at least one of the reflecting mirrors. 15. An X-ray exposure apparatus, comprising: 16. An apparatus according to claim 15, wherein at least one of said reflecting mirrors has an aspherical reflecting surface. 17. An apparatus according to claim 15, wherein at least one of said reflecting mirrors is provided with forced cooling means. 18. An apparatus according to claim 15, wherein helium gas flows through a space between at least two of the reflecting mirrors. 19. An X-ray reduction exposure apparatus, comprising: 20. An apparatus according to claim 19, wherein said rectangular area is oblong. 21. An apparatus according to claim 19, wherein the wafer is exposed to the reduced image of the mask pattern with X-rays. 22. An X-ray reduction exposure apparatus, comprising: 23. An apparatus according to claim 22, wherein at least one of said plural mirrors is provided with a multi-layer film coating. 24. An apparatus according to claim 22, wherein at least one of said plural mirrors has an aspherical reflecting surface. 25. An apparatus according to claim 22, wherein the visible light is a laser beam. 26. A reduction exposure apparatus, comprising: 27. An X-ray reflecting imaging system, comprising: 28. A system according to claim 27, wherein said first concave mirror is provided with forced cooling means. 29. A system according to claim 27, wherein a space between said first and second concave mirrors is filled with helium gas. 30. An X-ray reflecting imaging system, comprising: 31. A system according to claim 30, wherein each of said mirrors are provided with multi-layer coatings. 32. A system according to claim 30, wherein the minimized aberrations are maintained within an area in a rectangular form. 33. A system according to claim 30 wherein said imaging system is a reduction imaging system. 34. A system according to claim 30, wherein said imaging system is used as an enlarging imaging system. 35. A system for producing an image of an object using X-rays, said system comprising: 36. A system according to claim 35, wherein the object and the plane are located on opposite sides of the system axis. 37. A system according to claim 35, wherein a position of a front focus of said imaging means is coincident with a position of an entrance pupil. 38. An X-ray projection exposure apparatus for exposing a member sensitive to X-rays to a reduced image of a mask pattern with the X-rays, said apparatus comprising: 39. An apparatus according to claim 38, wherein said second, third and fourth mirrors are optically coaxial. 40. An apparatus according to claim 39, wherein said first mirror is eccentric from a coaxis of said second, third and fourth mirrors. 41. An apparatus according to claim 38, wherein said third mirror has an eccentric opening for allowing the X-rays reflected by said fourth mirror to pass through said third mirror. 42. An apparatus according to claim 38, wherein said fourth mirror has an eccentric opening to allow the X-rays toward and away from said second mirror to pass through said fourth mirror. 43. An apparatus according to claim 38, wherein said holder, stage allows the X-rays to pass therethrough, so that the mask, which is of a transmitting type, is usable. 44. An apparatus according to claim 38, wherein said mask holder is disposed between said inlet port and said first mirror. 45. An apparatus according to claim 38, wherein said inlet port and said first mirror face a same side of the mask holder, so that the mask, which is of a reflection type, is usable. 46. An X-ray exposure apparatus, comprising: 47. A system according to claim 35, wherein the image is produced by only one side of at least one of said reflecting elements. 48. An X-ray exposure apparatus comprising: 49. An apparatus according to claim 48, further comprising an illumination system for illuminating the original to project the image onto the substrate. 50. An apparatus according to claim 49, wherein said illumination system comprises a radiation source for emitting X-rays to illuminate the original. 51. An apparatus according to claim 50, wherein said mirror assembly comprises means for forming the image with X-rays reflected by the original. 52. An apparatus according to claim 50, wherein said mirror assembly comprises means for forming a reduced image of the pattern. 53. An apparatus according to claim 52, wherein said mirror assembly comprises a first concave mirror having a radius of curvature r1 with respect to its optical axis, a convex mirror having a radius of curvature r2 with respect to its optical axis and a second concave mirror having a radius of curvature R3 with respect to its optical axis, said mirrors being disposed in the named order from said illumination system, so that the conditions 0.9&lt;r2/r1+r2/r3&lt;1.1 are satisfied. 54. An apparatus according to claim 50, wherein said mirror assembly comprises a plurality of mirrors having multi-layer coating reflection surfaces. 55. A method of manufacturing a semiconductor device, said method comprising: 56. A method according to claim 55, further comprising illuminating the original with X-rays from an illumination system, receiving the X-rays through the original by the mirror assembly and forming the image by the X-rays. 57. A method according to claim 56, further comprising providing the mirror assembly with a plurality of mirrors, at least one of the plurality of mirrors being provided with the aspherical reflection surface. 58. A method according to claim 57, further comprising providing the plurality of mirrors of the assembly with multi-layer coating reflection surfaces. 59. A method according to claim 57, further comprising providing the mirror assembly with a first concave mirror having a radius of curvature r1 with respect to its optical axis, a convex mirror having a radius of curvature r2 with respect to its optical axis and a second concave mirror having a radius of curvature r3 with respect to its optical axis, the mirrors being disposed in the named order from the illumination system, so that the conditions 0.9&lt;r2/r1+r2/r3&lt;1.1 are satisfied. 60. A method according to claim 56, further comprising forming a reduced image of the pattern by the mirror assembly. 61. A method according to claim 56, further comprising supplying the X-rays from a synchrotron radiation source. 62. A pattern transfer apparatus comprising: 63. An apparatus according to claim 62, wherein said projection system comprises at least three curved reflection surface mirrors. 64. A pattern transfer apparatus comprising: 65. An apparatus according to claim 64, wherein said projection system comprises at least three curved reflection surface mirrors. 66. A pattern transfer apparatus comprising: 67. A semiconductor manufacturing method comprising: 68. A method according to claim 67, further comprising providing the projection system with at least three curved reflection surface mirrors. 69. A semiconductor manufacturing method comprising: 70. A method according to claim 69, further comprising providing the projection system with at least three curved reflection surface mirrors. 71. A semiconductor manufacturing method comprising: