There is provided a reflective image-forming optical system which is applicable to an exposure apparatus using, for example, EUV light and which is capable of increasing numerical aperture while enabling optical path separation of light fluxes. In a reflective imaging optical system (6) forming an image of a first plane (4) onto a second plane (7), the numerical aperture on a side of the second plane with respect to a first direction (X direction) on the second plane is greater than 1.1 times a numerical aperture on the side of the second plane with respect to a second direction (Y direction) crossing the first direction on the second plane. The reflecting imaging optical system has an aperture stop (AS) defining the numerical aperture on the side of the second plane, and the aperture stop has an elliptic-shaped opening of which size in a major axis direction (X direction) is greater than 1.1 times that in a minor axis direction (Y direction).

An optical lithography system is provided, comprising: a polygonal structure having a central region and a central axis; an UV light source detachably disposed in the central region or at an end of the polygonal structure; a light parallelizer positioned in the polygonal structure for creating substantially parallel light rays from the UV light source exiting the polygonal structure before reaching a lithography target adjacent to an exit of the polygonal structure, which includes at least three mirrors arranged such that the first mirror receives incident light from the UV light source and reflects thereof from the first mirror towards the second mirror, the second mirror receiving the reflected light as a second incident light and reflecting thereof from the second mirror towards the third mirror to create a spiral light path from the UV light source to the lithography target with substantially parallel light incident on the lithography target.

An optical lithography system is provided, comprising: a polygonal structure having a central region and a central axis; an UV light source detachably disposed in the central region or at an end of the polygonal structure; a light parallelizer positioned in the polygonal structure for creating substantially parallel light rays from the UV light source exiting the polygonal structure before reaching a lithography target adjacent to an exit of the polygonal structure, which includes at least three mirrors arranged such that the first mirror receives incident light from the UV light source and reflects thereof from the first mirror towards the second mirror, the second mirror receiving the reflected light as a second incident light and reflecting thereof from the second mirror towards the third mirror to create a spiral light path from the UV light source to the lithography target with substantially parallel light incident on the lithography target.

A lithographic apparatus includes a projection system which includes a plurality of optical elements configured to project a beam of radiation onto a radiation sensitive substrate. The lithographic apparatus also includes a metrology frame structure which includes a part of one or more optical element measurement systems to measure the position and/or orientation of at least one of the optical elements. The plurality of optical elements, a patterning device stage, and a substrate stage are arranged such that, in a two dimensional view on the projection system, a rectangle is defined such that it envelops the plurality of optical elements, the patterning device stage, and the substrate stage. The rectangle is as small as possible. The metrology frame structure is positioned within the rectangle.

An illumination optical system is used with a reflective imaging optical system configured to form an image of a pattern arranged on a first plane onto a second plane, and is configured to illuminate an illumination area on the first plane with a light from a light source. The illumination optical system includes one or more reflecting mirrors configured to reflect the light from the light source to the first plane such that the reflected light reaches the first plane after crossing an optical path of a light which travels in the reflective imaging optical system.

An optical system transfers original structure portions (13) of a lithography mask (10), which have an x/y-aspect ratio of greater than 4:1, and are aligned on the lithography mask, separated respectively by separating portions (14) that carry no structures to be imaged. The optical system transfers the original structure portions onto image portions (31) of a substrate (26). Each of the original structure portions is transferred to a separate image portion. The image portions onto which the original structure portions are transferred are arranged in a line next to one another. An associated projection optical unit may have an anamorphic embodiment with different imaging scales for two mutually perpendicular field coordinates specifically, one that is reducing for one of the field coordinates and the other is magnifying for the other field coordinates.

An illumination optical unit for projection lithography illuminates an object field with illumination light along an illumination beam path. The arrangement of field facets of a field facet mirror and also of pupil facets of a pupil facet mirror is such that an illumination channel is guided over each of them. The field facet mirror images a light source image along in each case one illumination channel onto one of the pupil facets. The pupil facet mirror superimposedly images of the field facets into the object field. The illumination optical unit is designed for the settable specification of a spatial resolution of an illumination light illumination of an entrance pupil of a projection optical unit arranged downstream of the object field in the illumination light beam path. The result of this is an illumination optical unit with which illumination light can be used efficiently for high-contrast imaging of the structures to be projected.

A lithographic apparatus includes a projection system which includes a plurality of optical elements configured to project a beam of radiation onto a radiation sensitive substrate. The lithographic apparatus also includes a metrology frame structure which includes a part of one or more optical element measurement systems to measure the position and/or orientation of at least one of the optical elements. The plurality of optical elements, a patterning device stage, and a substrate stage are arranged such that, in a two dimensional view on the projection system, a rectangle is defined such that it envelops the plurality of optical elements, the patterning device stage, and the substrate stage. The rectangle is as small as possible. The metrology frame structure is positioned within the rectangle.

A system includes a plate configured for mounting of a reflective extreme ultra-violet (EUV) mask thereon and a zone plate configured to divide EUV light into zero-order light and first-order light and to pass the zero-order light and the first-order light to the reflective EUV mask. The system further includes a detector configured to receive EUV light reflected by the EUV mask and including a zero-order light detection region configured to generate a first image signal and a first-order light detection region configured to generate a second image signal, and a calculator configured to generate a compensated third image signal from the first image signal and the second image signal. The third image signal may be used to determine a distance between mask patterns of the EUV mask.

A catoptric system having a reference axis and including a reflective pattern-source (carrying a substantially one-dimensional pattern) and a combination of only three optical components disposed sequentially to transfer EUV radiation incident the first optical component onto the pattern-source. The combination is disposed in a fixed spatial and optical relationship with respect to the pattern-source, and represents an illumination unit (IU) of a 1D EUV exposure tool that additionally includes a projection optic sub-system configured to form an optical image of the pattern-source on an image plane with the use of only two beams of radiation. These only two beams of radiation originate at the pattern-source from the EUV radiation transferred onto the pattern-source.