Patent Number: 
Section: claims

1. An illumination optical unit, comprising:a hollow waveguide configured to guide EUV light from an entry opening of the hollow waveguide to an exit opening of the hollow waveguide during use of the illumination optical unit; andan imaging mirror optical unit downstream of the hollow waveguide along a path of the EUV light through the illumination optical unit during use of the illumination optical unit,wherein:the imaging mirror optical unit comprises first and second mirrors, which are the only mirrors of the imaging optical unit;a minimum distance between optically used faces of the first and second mirrors is less than 300 mm;during use of the illumination optical unit:the EUV light impinges on the first mirror and then the second mirror without impinging on a reflective surface between the first and second mirrors; andthe EUV light impinges on the first mirror and then the second mirror without any vector of the EUV light reversing direction;for each of the first and second mirrors, the EUV light is incident on the mirror with a mean angle of incidence greater than 60°; andthe imaging mirror optical unit is configured to image the exit opening of the hollow waveguide into an illumination field to illuminate a mask located in the illumination field. 2. The illumination optical unit of claim 1, wherein the imaging mirror optical unit comprises a Wolter telescope. 3. The illumination optical unit of claim 1, wherein a mirror selected from the group consisting of the first mirror and the second mirror comprises an ellipsoid mirror. 4. The illumination optical unit of claim 1, wherein a mirror selected from the group consisting of the first mirror and the second mirror comprises a hyperboloid mirror. 5. The illumination optical unit of claim 1, wherein a minimum angle of incidence of the EUV light in the hollow waveguide is greater than 80°. 6. The illumination optical unit of claim 1, wherein an overall reflectivity of the illumination optical unit for the EUV light is greater than 40%. 7. The illumination optical unit of claim 1, wherein the first mirror comprises an ellipsoid mirror, and the second mirror comprises an ellipsoid mirror. 8. The illumination optical unit of claim 1, wherein the first mirror comprises a hyperboloid mirror, and the second mirror comprises a hyperboloid mirror. 9. A system, comprising:an EUV light source;an illumination optical unit, comprising:a hollow waveguide configured to guide EUV light from an entry opening of the hollow waveguide to an exit opening of the hollow waveguide during use of the system; andan imaging mirror optical unit downstream of the hollow waveguide along a path of the EUV light through the illumination optical unit during use of the system, the imaging mirror optical unit being configured to image the exit opening of the hollow waveguide into an illumination field;a projection optical unit configured to image the illumination field into an image field; anda detection device configured to detect EUV incident on the image field,wherein:the imaging mirror optical unit comprises first and second mirrors, which are the only mirrors of the imaging optical unit;a minimum distance between optically used faces of the first and second mirrors is less than 300 mm; andduring use of the illumination optical unit:the EUV light impinges on the first mirror and then the second mirror without impinging on a reflective surface between the first and second mirrors;the EUV light impinges on the first mirror and then the second mirror without any vector of the EUV light reversing; andfor each of the first and second mirrors, the EUV light is incident on the mirror with a mean angle of incidence greater than 60°. 10. The system of claim 9, wherein the imaging mirror optical unit comprises a Wolter telescope. 11. The system of claim 9, wherein a minimum angle of incidence of the EUV light in the hollow waveguide is greater than 80°. 12. The system of claim 9, wherein an overall reflectivity of the illumination optical unit for the EUV light is greater than 40%. 13. The system of claim 9, wherein the first mirror comprises an ellipsoid mirror, and the second mirror comprises an ellipsoid mirror. 14. The system of claim 9, wherein the first mirror comprises a hyperboloid mirror, and the second mirror comprises a hyperboloid mirror. 15. A method, comprising:using an illumination optical unit to illuminate a lithography mask in an illumination field with EUV light, the illumination optical unit comprising:a hollow waveguide configured to guide the EUV light from an entry opening of the hollow waveguide to an exit opening of the hollow waveguide; andan imaging mirror optical unit downstream of the hollow waveguide along a path of the EUV light through the illumination optical unit,wherein:the imaging mirror optical unit comprises first and second mirrors, which are the only mirrors of the imaging optical unit;a minimum distance between optically used faces of the first and second mirrors is less than 300 mm;during the method:the EUV light impinges on the first mirror and then the second mirror without impinging on a reflective surface between the first and second mirrors;the EUV light impinges on the first mirror and then the second mirror without any vector of the EUV light reversing; andfor each of the first and second mirrors, the EUV light is incident on the mirror with a mean angle of incidence greater than 60°; andthe imaging mirror optical unit images the exit opening of the hollow waveguide into an illumination field. 16. The method of claim 15, further comprising using a projection optical unit to project an image of the lithography mask into an image field. 17. The method of claim 16, further comprising detecting EUV light incident on the image field. 18. The method of claim 15, further comprising detecting EUV light incident on the image field. 19. The method of claim 15, wherein the first mirror comprises an ellipsoid mirror, and the second mirror comprises an ellipsoid mirror. 20. The method of claim 15, wherein the first mirror comprises a hyperboloid mirror, and the second mirror comprises a hyperboloid mirror.