Patent Number: 
Section: claims

1. A grazing incidence reflector for extreme ultraviolet (EUV) radiation, comprising:a first mirror layer configured to reflect at least partially EUV radiation incident on the reflector with grazing incidence angles in a first range, the first mirror layer being configured to transmit EUV radiation in a second range of incidence angles which overlaps and extends beyond the first range of incidence angles;a multilayer mirror structure beneath the first mirror layer configured to reflect EUV radiation which is incident on the reflector with grazing incidence angles in said second range and which penetrates through the first mirror layer; anda second mirror layer on top of the first mirror layer, the second mirror layer being configured to provide enhanced reflectance for EUV radiation with grazing incidence angles in a third range which is within the first range of angles. 2. The grazing incidence reflector according to claim 1, wherein the first mirror layer has a thickness of less than 20 nm. 3. The grazing incidence reflector according to claim 1, wherein the second mirror layer has a thickness of less than 10 nm and has a reflectance greater than 40% over a range of grazing incidence angles extending from 0 degree to less than 10 degrees. 4. The grazing incidence reflector according to claim 1,wherein the first mirror layer occupies only a portion of a surface of the multilayer mirror structure so as to provide enhanced reflectance for EUV radiation with grazing incidence angles in the second range. 5. The grazing incidence reflector according to claim 1, wherein the reflector is configured for operation at EUV wavelengths in the range 6-7 nm. 6. The grazing incidence reflector according to claim 5, wherein the first mirror layer has a thickness in the range 15-17 nm and is made of ThO2, and has a reflectance greater than 40% over the first range of grazing incidence angles between greater than 0 degree and less than 12 degrees. 7. The grazing incidence reflector according to claim 6, wherein:the second range of grazing incidence angles is greater than or equal to 12 degrees and less than or equal to 14 degrees; andthe multilayer mirror structure is formed of a number of laminated elements, each laminated element having a first sub-unit and a second sub-unit on top of the first sub-unit, the second sub-unit having a lower index of refraction than that of the first sub-unit. 8. The grazing incidence reflector according to claim 7, wherein materials of the first sub-unit and the second sub-unit are selected from a group of Th, La, U, B, nitrides, oxides, borides, fluorides of heavy metal elements, and carbides of light elements. 9. The grazing incidence reflector according to claim 1, wherein the reflector is configured for operation at EUV wavelengths in the range 13-14 nm. 10. The grazing incidence reflector according to claim 9, wherein the first mirror layer has a thickness in the range 15-17 nm and is made of Ru, and has a reflectance greater than 40% over the first range of grazing incidence angles between greater than 0 degree and less than 25 degrees. 11. The grazing incidence reflector according to claim 10, wherein:the second range of grazing incidence angles is greater than or equal to 25 degrees and less than or equal to 30 degrees; andthe multilayer mirror structure is formed of a number of laminated elements, each laminated element having a first sub-unit and a second sub-unit on top of the first sub-unit, the second sub-unit having a lower index of refraction than that of the first sub-unit. 12. The grazing incidence reflector according to claim 11, wherein materials of the first sub-unit and the second sub-unit are selected from a group of Mo, Si, Ru and diamond-like carbon. 13. The grazing incidence reflector according to claim 1wherein at least one of a period and a composition of the multilayer mirror structure varies across the multilayer mirror structure so that a grazing incidence angle of maximal reflectance varies across the multilayer mirror structure. 14. A lithographic apparatus comprising a grazing incidence reflector comprising:a first mirror layer configured to reflect at least partially EUV radiation incident on the reflector with grazing incidence angles in a first range, the first mirror layer being configured to transmit EUV radiation in a second range of incidence angles which overlaps and extends beyond the first range of incidence angles;a multilayer mirror structure beneath the first mirror layer configured to reflect EUV radiation which is incident on the reflector with grazing incidence angles in said second range and which penetrates through the first mirror layer, anda second mirror layer on top of the first mirror layer, the second mirror layer being configured to provide enhanced reflectance for EUV radiation with grazing incidence angles in a third range which is within the first range of angles. 15. A method for manufacturing a grazing incidence reflector configured to reflect extreme ultraviolet (EUV) radiation, the method comprising:disposing a first mirror layer on top of a multilayer mirror structure and a surface structure on top of the multilayer mirror structure; anddisposing a second mirror layer on top of the first mirror layer; wherein the first mirror layer is configured to at least partially reflect EUV radiation incident on the reflector with grazing incidence angles in a first range, the first mirror layer being configured to transmit EUV radiation in a second range of incidence angles which overlaps and extends beyond the first range of incidence angles, and the second mirror layer being configured to provide enhanced reflectance for EUV radiation with grazing incidence angles in a third range which is within the first range of angles; andthe multilayer mirror structure is configured to reflect EUV radiation which is incident on the reflector with grazing incidence angles in said second range and which penetrates through the first mirror layer. 16. A method for manufacturing a device by a lithographic process, comprising:illuminating a patterning device with extreme ultraviolet (EUV) radiation from an EUV source via an illumination system; andprojecting an image of the patterning device onto a substrate by projection of said EUV radiation via projection system;wherein at least one of the illumination system or the projection system comprises a grazing incidence reflector for:reflecting at least partially EUV radiation incident on the reflector with grazing incidence angles in a first range with a first mirror layer being configured to transmit EUV radiation in a second range of incidence angles which overlaps and extends beyond the first range of incidence angles;providing enhanced reflectance for EUV radiation with grazing incidence angles in a third range which is within the first range of angles with a second mirror layer on top of the first mirror layer; andreflecting EUV radiation which is incident on the reflector with grazing incidence angles in said second range and which penetrates through the first mirror layer with a multilayer mirror structure beneath the first mirror layer. 17. A method for manufacturing a grazing incidence reflector configured to reflect extreme ultraviolet (EUV) radiation, the method comprising:disposing a first mirror layer on top of a multilayer mirror structure and a surface structure on top of the multilayer mirror structure;wherein the first mirror layer is configured to at least partially reflect EUV radiation incident on the reflector with grazing incidence angles in a first range, the first mirror layer being configured to transmit EUV radiation in a second range of incidence angles which overlaps and extends beyond the first range of incidence angles, and the first mirror layer occupies only a portion of a surface of the multilayer mirror structure so as to provide enhanced reflectance for EUV radiation with grazing incidence angles in the second range; andthe multilayer mirror structure is configured to reflect EUV radiation which is incident on the reflector with grazing incidence angles in said second range and which penetrates through the first mirror layer.