Patent Number: 
Section: claims

1. An optical apparatus for radiation having a wavelength xe2x89xa6160 nm, comprising: a mirror with a mirror surface; and  a device for producing elastic oscillations on said mirror surface,  wherein said elastic oscillations cause radiation impinging on said mirror surface to be diffracted. 2. The optical apparatus of  claim 1 , wherein said device generates surface acoustical waves on said mirror surface produce said elastic oscillations. claim 1 3. The optical apparatus of  claim 2 , wherein said surface acoustical waves produce a diffraction grid on said mirror surface. claim 2 4. The optical apparatus of  claim 2 , wherein said surface acoustical waves have a wavelength in the range of about 1 xcexcm to 50 xcexcm. claim 2 5. The optical apparatus of  claim 2 , wherein said surface acoustical waves have an amplitude in the range of about 1 nm to 100 nm. claim 2 6. The optical apparatus of  claim 2 , wherein said surface acoustical waves have a frequency that is varied. claim 2 7. The optical apparatus of  claim 2 , claim 2 wherein said device is a first device and said surface acoustical waves are first surface acoustical waves, and  wherein said optical apparatus further comprises:  a second device for generating second acoustical waves on said mirror surface,  wherein said second surface acoustical waves are parallel to said first surface acoustical waves. 8. The optical apparatus of  claim 7 , wherein said mirror surface comprises a plurality of individual mirror surfaces. claim 7 9. The optical apparatus of  claim 2 , claim 2 wherein said device is a first device and said surface acoustical waves are first surface acoustical waves, and  wherein said optical apparatus further comprises:  a second device for generating second acoustical waves on said mirror surface,  wherein said second surface acoustical waves are not parallel to said first surface acoustical waves. 10. The optical apparatus of  claim 9 , wherein said mirror surface comprises a plurality of individual mirror surfaces. claim 9 11. A method, using the optical apparatus of  claim 2 , for illuminating a predetermined range of angles (xcex1) with said radiation, said method comprising: claim 2 generating said surface acoustical waves; and  varying a frequency of said surface acoustical waves,  wherein said surface acoustical waves produce a plurality of grid lines on said mirror surface,  wherein said radiation impinges two or more of said plurality of grid lines, and  wherein said radiation is diffracted in said predetermined range of angles (xcex1) and, when averaged over time, homogeneously illuminates said predetermined range of angles (xcex1). 12. The method of  claim 11 , wherein said predetermined range of angles (xcex1) is about xe2x88x9212.0 mrad xe2x89xa6xcex1xe2x89xa612.0 mrad. claim 11 13. The optical apparatus of  claim 1 , wherein said device comprises a piezoelectric foil. claim 1 14. The optical apparatus of  claim 13 , wherein said piezoelectric foil is a PZT film. claim 13 15. The optical apparatus of  claim 1 , wherein said device comprises a piezoeleetne crystal. claim 1 16. The optical apparatus of  claim 1 , wherein said device comprises a point-like or linear-form electrode. claim 1 17. The optical apparatus of  claim 1 , wherein the optical apparatus is a component in an exposure device for lithography. claim 1 18. The optical apparatus of  claim 17 , wherein said exposure device comprises a source of said raditation, and wherein the optical apparatus broadens a beam of said source. claim 17 19. The optical apparatus of  claim 17 , wherein said exposure device comprises an illumination system, and wherein the optical apparatus varies an illumination setting of said illumination system. claim 17 20. The optical apparatus of  claim 17 , wherein the optical apparatus homogenizes an illumination of a pupil of said exposure device. claim 17 21. A method for producing the optical apparatus of  claim 1 , comprising: claim 1 superpolishing a side of a substrate to yield a surface roughness of less than about 0.5 nm; and  attaching an electrode to said substrate,  wherein said mirror surface comprises said side of said substrate, and  wherein said device comprises said electrode. 22. The method of  claim 21 , wherein said electrode is attached to said superpolished side of said substrate. claim 21 23. The optical apparatus of  claim 1 , wherein said device comprises a piezoelectric foil. claim 1 24. The optical apparatus of  claim 1 , wherein said elastic oscillations generate a plurality of diffraction grids on said mirror surface. claim 1 25. The optical apparatus of  claim 24 , wherein said plurality of diffraction grids are provided by varying a frequency of said elastic oscillations. claim 24 26. The optical apparatus of  claim 1 , wherein said device is a first device, and wherein said optical apparatus further comprises a second device for producing elastic oscillations on said mirror surface. claim 1 27. The optical apparatus of  claim 26 , wherein said first and second devices are arranged on said mirror surface so that a beam of said radiation impinging on said mirror surface is modified in two dimensions. claim 26 28. The optical apparatus of  claim 1 , wherein said device comprises an interdigital transformer. claim 1 29. An illumination system for microlithography having a radiation source for emitting radiation having a wavelength xe2x89xa6160 nm, comprising the optical apparatus of  claim 1 . claim 1 30. A projection exposure apparatus for microlithography, comprising: the illumination system of  claim 29 , for illuminating an object; and  claim 29 a projection objective for imaging said object onto a light sensitive substrate. 31. An optical apparatus for radiation having a wavelength xe2x89xa6160 nm, comprising: a mirror with a mirror surface; and  a device for producing elastic oscillations on said mirror surface,  wherein said elastic oscillations cause radiation impinging on said mirror surface to be diffracted in a predetermined range of angles (xcex1), and  wherein said predetermined range of angles (xcex1) is about xe2x88x9212 mrad=xcex1=mrad.