Patent Number: 
Section: claims

1. An illumination system, comprising:a collector configured to concentrate EUV radiation emitted by a source by reflection in the direction of an optical axis, along which the EUV radiation is guided by successive optical elements,a first optical element being a first facet mirror,a second optical element being a second facet mirror configured to guide the EUV radiation, reflected by the first optical element, along the optical axis, and the second optical element configured to image the first optical element into the illumination field arranged in an image plane which coincides with the object surface,wherein:a maximum of five reflecting elements are arranged between the collector and the illumination field;the optical axis meets the reflecting optical elements at an angle of incidence which is either greater than 60° or less than 30°,an axis angle of deflection between a source axis portion of the optical axis, which runs between the collector and the first optical element, or of the projection of this source axis portion of the optical axis onto an illumination main plane, which lies vertically on the image plane, and in which a field axis portion, which with the image plane encloses an angle less than 90°, of the optical axis runs between a last element of the illumination system and the illumination field, and the field axis portion of the optical axis or a projection of the field axis portion of the optical axis onto the illumination main plane is greater than 30°; andat least an axis portion of the optical axis is inclined between at least two of the optical elements relative to the illumination main plane. 2. An illumination system according to claim 1, wherein a size of the illumination field is at least 100 mm2. 3. An illumination system according to claim 1, wherein the second optical element is part of an optical device which includes further optical elements, and which guides the EUV radiation reflected by the first optical element along the optical axis, and images the first optical element into the illumination field being arranged in the image plane, which coincides with the object surface. 4. An illumination system according to claim 3, wherein the optical device includes at least fourth and fifth optical elements after the second optical element, and an axis portion of the optical axis is inclined between the third and the fourth optical elements relative to the illumination main plane. 5. An illumination system according to claim 3, wherein the optical device includes at least fourth and fifth optical elements after the second optical element, and an axis portion of the optical axis is inclined between the first and second optical elements relative to the illumination main plane. 6. An illumination system according to claim 4, wherein an axis portion between the second and the third element of the optical device is inclined relative to the illumination main plane. 7. An illumination system according to claim 1, wherein:after the second optical element, a maximum of two further optical elements are provided;an axis portion of the optical axis between the collector and the first optical element is inclined relative to the illumination main plane; andthe source of the EUV radiation is a plasma source. 8. An illumination system according to claim 1, wherein:after the second optical element only one further optical element is provided;an axis portion of the optical axis between the collector and the first optical element is inclined relative to the illumination main plane; andthe source of the EUV radiation is a plasma source. 9. An illumination system according to claim 1, whereinafter the second optical element, a maximum of two further optical elements are provided;an axis portion of the optical axis between the collector and the first optical element is inclined relative to the illumination main plane;the source of the EUV radiation is a plasma source; andthe collector is in such a form that the EUV radiation is concentrated by at most two reflections on the collector. 10. An illumination system according to claim 1, whereinafter the second optical element only one further optical element is provided;an axis portion of the optical axis between the collector and the first optical element is inclined relative to the illumination main plane;the source of the EUV radiation is a plasma source; andthe collector is in such a form that the EUV radiation is concentrated by at most by two reflections on the collector. 11. An illumination system according to claim 7, wherein an axis portion of the optical axis between the first and second optical elements is inclined relative to the illumination main plane. 12. An illumination system according to claim 1, wherein:the optical device, in addition to the second optical element, includes only two further optical elements; andan axis portion of the optical axis between the collector and the first optical element and an axis portion of the optical axis between the second optical element and the third optical element is inclined relative to the illumination main plane. 13. An illumination system, comprising:a collector configured to concentrate EUV radiation emitted by a source by reflection in the direction of an optical axis, along which the EUV radiation is guided by successive optical elements;a first optical element being a first facet mirror;a second optical element being a second facet mirror configured to guide the EUV radiation, reflected by the first optical element, along the optical axis, and configured to image the first optical element into the illumination field being arranged in an image plane, which coincides with the object surface,wherein:between the collector and the illumination field, a maximum of five reflecting optical elements are arranged,the optical axis meeting the reflecting optical elements at an angle of incidence which is either greater than 60° or less than 30°;an axis angle of deflection between a source axis portion of the optical axis, which runs between the collector and the first optical element, or of the projection of this source axis portion of the optical axis onto an illumination main plane, which lies vertically on the image plane, and in which a field axis portion, which with the image plane encloses an angle less than 90°, of the optical axis runs between a last element of the illumination system and the illumination field, and the field axis portion of the optical axis or a projection of the field axis portion of the optical axis onto the illumination main plane is greater than 30°;the optical device, in addition to the second optical element, includes only a third optical element, a fourth optical element and a fifth optical element; andthe optical axis meeting the third, fourth and fifth optical elements at an angle of incidence which is greater than 60°. 14. An illumination system according to claim 1, wherein a numerical aperture of the illumination is at least 0.02. 15. An illumination system according to claim 1, wherein a size of the illumination field is at least 500 mm2. 16. A system, comprising:an illumination system according to claim 1,wherein the system is a projection exposure system. 17. A method, comprising:providing a substrate, a reticle and a projection exposure system, the projection exposure system comprising an illumination system according to claim 1; andusing the projection exposure system to project at least a portion of the reticle onto an area of a light-sensitive layer of the substrate. 18. The method of claim 17, comprising using the method to produce a structured component. 19. An illumination system, comprising:a collector configured to concentrate EUV radiation emitted by a source by reflection in the direction of an optical axis, along which the EUV radiation is guided by successive optical elements,a first optical element being a first facet mirror,a second optical element being a second facet mirror configured to guide the EUV radiation, reflected by the first optical element, along the optical axis, and the second optical element configured to image the first optical element into the illumination field arranged in an image plane which coincides with the object surface,wherein:a maximum of five reflecting elements are arranged between the collector and the illumination field;the optical axis meets the reflecting optical elements at an angle of incidence which is either greater than 60° or less than 30°;an axis angle of deflection between a source axis portion of the optical axis, which runs between the collector and the first optical element, or of the projection of this source axis portion of the optical axis onto an illumination main plane, which lies vertically on the image plane, and in which a field axis portion, which with the image plane encloses an angle less than 90°, of the optical axis runs between a last element of the illumination system and the illumination field, and the field axis portion of the optical axis or a projection of the field axis portion of the optical axis onto the illumination main plane is greater than 30°; andan axis portion of the optical axis between the collector and the first optical element is inclined relative to the illumination main plane. 20. A system, comprising:an illumination system according to claim 19,wherein the system is a projection exposure system. 21. A method, comprising:providing a system that includes a substrate, a reticle and a projection exposure system comprising an illumination system according to claim 19; andusing the projection exposure system to project at least a portion of the reticle onto an area of a light-sensitive layer of the substrate. 22. The method of claim 21, comprising using the method to produce a structured component. 23. A system, comprising:an illumination system according to claim 13,wherein the system is a projection exposure system. 24. A method, comprising:providing a system that includes a substrate, a reticle and a projection exposure system comprising an illumination system according to claim 13; andusing the projection exposure system to project at least a portion of the reticle onto an area of a light-sensitive layer of the substrate. 25. The method of claim 24, comprising using the method to produce a structured component. 26. The illumination system of claim 19, wherein an axis portion of the optical axis is inclined between at least two of the optical elements relative to the illumination main plane.