Patent Number: 055486258
Section: claims

1. A method for performing parallel multiple field processing in x-ray lithography comprising the steps of: a) placing a semiconductor wafer on a support stage for holding the semiconductor wafer;  b) providing an x-ray source;  c) providing a mirror assembly containing at least two mirrored surfaces each having a length;  d) providing means for containing the mirror assembly, wherein the length of the at least two mirrored surfaces is positioned along a length of the means for containing the mirror assembly to act as collimating mirrors;  e) providing a mask assembly containing a same number of masks as mirrored surfaces in the mirror assembly, wherein the mask assembly maintains a first fixed separation distance between each mask for forming multiple and separate image fields;  f) aligning the semiconductor wafer with respect to the mask assembly;  g) focusing a first surface portion of the semiconductor wafer with respect to the mask assembly;  h) exposing the first surface portion of the semiconductor wafer to at least two exiting x-ray beams formed by the collimating mirrors which collimate photons emitted by the x-ray source which is projected into a first end of the means for containing the mirror assembly such that the at least two exiting x-ray beams are collimated and reflected off the at least two mirrored surfaces to travel through the length of the means for containing the mirror assembly to exit a second end of the means for containing the mirror assembly, wherein the at least two mirrored surfaces form the at least two exiting x-ray beams having a second fixed separation distance between the at least two exiting x-ray beams such that each of the at least two exiting x-ray beams travels through a separate mask of the mask assembly to print the multiple and separate image fields on the semiconductor wafer; and  i) stepping to a next surface portion of the semiconductor wafer and repeating steps (g) through (i) until all desired surface portions of the semiconductor wafer are exposed.  a) placing a semiconductor wafer on a support stage for holding the semiconductor wafer;  b) providing an x-ray source;  c) providing a monolithic mirror assembly containing at least two mirrored surfaces each having a length;  d) providing an elongated tube, suitably evacuated, for containing the monolithic mirror assembly, wherein the length of the at least two mirrored surfaces is positioned along a length of the elongated tube to act as collimating mirrors;  e) providing, external to the elongated tube but aligned thereto, a mask assembly containing a same number of masks as mirrored surfaces in the monolithic mirror assembly, wherein the mask assembly maintains a first fixed separation distance between each mask for forming multiple and separate image fields;  f) aligning the semiconductor wafer with respect to the mask assembly;  g) focusing a first surface portion of the semiconductor wafer with respect to the mask assembly;  h) exposing the first surface portion of the semiconductor wafer to at least two exiting x-ray beams formed by the collimating mirrors which collimate photons emitted by the x-ray source which is projected into a first end of the elongated tube for containing the monolithic mirror assembly such that the at least two exiting x-ray beams are collimated and reflected off the at least two mirrored surfaces to travel through the length of the elongated tube to exit a second end of the elongated tube for containing the monolithic mirror assembly, wherein the at least two mirrored surfaces form the at least two exiting x-ray beams having a second fixed separation distance between the at least two exiting x-ray beams such that each of the at least two exiting x-ray beams travels through a separate mask of the mask assembly to print the multiple and separate image fields on the semiconductor wafer; and  i) stepping to a next surface portion of the semiconductor wafer and repeating steps (g) through (i) until all desired surface portions of the semiconductor wafer are exposed.  a) placing a semiconductor wafer on a support stage for holding the semiconductor wafer;  b) providing an x-ray source;  c) providing a coupled mirror assembly containing at least two mirrors each having a length;  d) providing an elongated tube, suitably evacuated, for containing the coupled mirror assembly, wherein the length of the at least two mirrors is positioned along a length of the elongated tube to act as collimating mirrors;  e) providing, external to the elongated tube but aligned thereto, a mask assembly containing a same number of masks as mirrors in the coupled mirror assembly, wherein the mask assembly maintains a first fixed separation distance between each mask for forming multiple and separate image fields;  f) aligning the semiconductor wafer with respect to the mask assembly;  g) focusing a first surface portion of the semiconductor wafer with respect to the mask assembly;  h) exposing the first surface portion of the semiconductor wafer to at least two exiting x-ray beams formed by the collimating mirrors which collimate photons emitted by the x-ray source which is projected into a first end of the elongated tube for containing the coupled mirror assembly such that the at least two exiting x-ray beams are collimated and reflected off the at least two mirrors to travel through the length of the elongated tube to exit a second end of the elongated tube for containing the coupled mirror assembly, wherein the at least two mirrors form the at least two exiting x-ray beams having a second fixed separation distance between the at least two exiting x-ray beams such that each of the at least two exiting x-ray beams travels through a separate mask of the mask assembly to print the multiple and separate image fields on the semiconductor wafer; and  i) stepping to a next surface portion of the semiconductor wafer and repeating steps (g) through (i) until all desired surface portions of the semiconductor wafer are exposed. 2. The method of claim 1, wherein the step of placing the semiconductor wafer is further characterized as placing a wafer having a diameter of at least 200 millimeters. 3. The method of claim 1, wherein the step of providing the means for containing the mirror assembly provides an evacuated tube having a multiple beryllium exit window at the second end of the means for containing the mirror assembly. 4. The method of claim 1, wherein the step of providing the mirror assembly comprises providing a monolithic mirror having multiple mirrored surfaces having a shape selected from a group consisting of: flat, parabolic, circular, toroidal, cylindrical, and polynomial. 5. The method of claim 1, wherein the step of providing the mirror assembly comprises providing multiple separate mirrors mechanically coupled together and having a fixed physical separation between each mirror, wherein each mirror has a surface having a shape selected from a group consisting of: flat, parabolic, circular, toroidal, cylindrical, and polynomial. 6. The method of claim 1, wherein the step of providing the mask assembly provides multiple masks coupled together with means for coupling selected from a group consisting of: an interferometer, physical means, and electronic means. 7. The method of claim 1, wherein the step of providing the mask assembly provides a first mask used for aligning and focusing, and a second mask used only for focusing. 8. The method of claim 1, wherein the step of providing the mask assembly provides masks that are each used for aligning and focusing. 9. A method for performing parallel multiple field processing in x-ray lithography comprising the steps of: 10. The method of claim 9, wherein the step of placing the semiconductor wafer is further characterized as placing a wafer having a diameter of at least 200 millimeters. 11. The method of claim 9, wherein the step of providing the mask assembly provides multiple masks coupled together with means for coupling selected from a group consisting of: an interferometer, physical means, and electronic means. 12. The method of claim 9, wherein the step of providing the monolithic mirror assembly provides mirrored surfaces having a shape selected from a group consisting of: flat, parabolic, circular, toroidal, cylindrical, and polynomial. 13. The method of claim 9, wherein the step of providing the elongated tube for containing the monolithic mirror assembly comprises providing an ultra high vacuum tube, evacuated to a pressure of approximately in a range of 10.sup.-10 to 10.sup.-11 torr. 14. The method of claim 13, wherein the step of providing the elongated tube further provides a multiple beryllium exit window at the second end of the elongated tube. 15. The method of claim 9, wherein the step of providing the mask assembly provides a first mask used for aligning and focusing, and a second mask used only for focusing. 16. A method for performing parallel multiple field processing in x-ray lithography comprising the steps of: 17. The method of claim 16, wherein the step of placing the semiconductor wafer is further characterized as placing a wafer having a diameter of at least 200 millimeters. 18. The method of claim 16, wherein the step of providing the coupled mirror assembly comprises providing multiple separate mirrors mechanically coupled together to maintain a fixed physical separation between each mirror. 19. The method of claim 16, wherein the step of providing the coupled mirror assembly provides mirrors having a shape selected from a group consisting of: flat, parabolic, circular, toroidal, cylindrical, and polynomial. 20. The method of claim 16, wherein the step of providing a mask assembly provides multiple masks coupled together with means for coupling selected from a group consisting of: an interferometer, physical means, and electronic means.