An illumination system of a microlithographic projection exposure apparatus includes a spatial light modulator which varies an intensity distribution in a pupil surface. The modulator includes an array of mirrors that reflect impinging projection light into directions that depend on control signals applied to the mirrors. A prism, which directs the projection light towards the spatial light modulator, has a double pass surface on which the projection light impinges twice, namely a first time when leaving the prism and before it is reflected by the mirrors, and a second time when entering the prism and after it has been reflected by the mirrors. A pupil perturbation suppressing mechanism is provided that reduces reflections of projection light when it impinges the first time on the double pass surface, and/or prevents that light portions being a result of such reflections contribute to the intensity distribution in the pupil surface.

A method for reducing M3D effects on imaging is described. The method includes identifying points within a source plane of the photolithography system that are associated with pattern shifts resulting from diffraction of light off a photomask under an angle of incidence between an imaging beam of radiation and the mask normal, determining pattern shifts associated with the identified source plane points, and modifying the source to reduce the determined pattern shifts.

A facet mirror for an illumination optical unit of a projection exposure apparatus has a large number of displaceable individual facets with a facet main body and a reflection surface arranged on it. At least some of the individual facets have a displacement range such that they come into contact with a stop surface in one or more displacement positions.

An illuminator includes a first facet mirror receiving and reflecting an exposure radiation, an adjustable shielding element disposed on the first facet mirror, the adjustable shielding element adjusting intensity uniformity of the exposure radiation reflected by the first facet mirror, and a second facet mirror receiving and reflecting the exposure radiation reflected by the first facet mirror.

In accordance with some embodiments, a method of controlling an extreme ultraviolet (EUV) radiation in lithography system is provided. The method includes generating a plurality of target droplets. The method also includes generating a pre-pulse and a main pulse from an excitation laser module to generate EUV light and reflecting the EUV light by a collector mirror. The method further includes measuring a separation between a pre-pulse and a main pulse. Moreover, the method includes determining whether the separation between the pre-pulse and the main pulse in the y-axis is changed, if not adjusting a configurable parameter of the excitation laser module to set the variation in the energy of the EUV light within an acceptable range.

A measurement illumination optical unit guides illumination light into an object field of a projection exposure apparatus for EUV lithography. The illumination optical unit has a field facet mirror with a plurality of field facets and a pupil facet mirror with a plurality of pupil facets. The latter serve for overlaid imaging in the object field of field facet images of the field facets. A field facet imaging channel of the illumination light is guided via any one field facet and any one pupil facet. A field stop specifies a field boundary of an illumination field in the object plane. The illumination field has a greater extent along one field dimension than any one of the field facet images. At least some of the field facets include tilt actuators which help guide the illumination light into the illumination field via various field facets and one and the same pupil facet.

A formable material in contact with a template is irradiated to form a reference film using a predefined registration pattern associated with a spatial light modulator (SLM). The reference film is inspected to generate positional information of elements of the SLM relative to an imprint field edge. Positional offset of the elements of the SLM with respect to a holder of the template based on the positional information is determined. Control parameters for the SLM are determined based on the positional offset.

In accordance with some embodiments, a method of controlling an extreme ultraviolet (EUV) radiation in lithography system is provided. The method includes generating a plurality of target droplets. The method also includes generating a pre-pulse and a main pulse from an excitation laser module to generate EUV light and reflecting the EUV light by a collector mirror. The method further includes measuring a separation between a pre-pulse and a main pulse. Moreover, the method includes determining whether the separation between the pre-pulse and the main pulse in the y-axis is changed, if not adjusting a configurable parameter of the excitation laser module to set the variation in the energy of the EUV light within an acceptable range.

An optical arrangement for a lithography apparatus has a microsystem with a mirror array. A respective mirror of the mirror array is set up to reflect working light of the lithography apparatus on its front side and also a measuring beam on its rear side. One or more radiation sources, which are provided outside the microsystem, are set up to provide the respective measuring beam. One or more sensor units are set up to sense a tilting angle of a respective mirror in dependence on the respectively reflected measuring beam.

An optical system includes an illumination optical unit configured to guide illumination radiation along a path to an object plane. The illumination optical unit includes comprising a first facet mirror; a second facet mirror disposed downstream of the first facet mirror along the path; and a condenser mirror. The optical system also includes a projection optical unit configured to image a first article in the object plane onto a second article in an image plane. The image plane is a first distance from the object plane. The condenser mirror a second distance from the object plane. The second distance is greater than the first distance