Abstract: A method of lithographically transferring a pattern on a light sensitive surface in a multiple exposure process comprises the following steps: a) providing a mask comprising a first mask pattern area and a second mask pattern area; b) directing projection light on the mask, thereby producing on the light sensitive surface a first exposed pattern area, which is an image of the first mask pattern area, and a second exposed pattern area, which is an image of the second mask pattern area. The projection light illuminating the first and second mask pattern area has different angular light distributions. c) repeating step b) using the same mask so that an image of the first mask pattern area is superimposed on the second exposure pattern area.

Abstract: A microlithography optical system includes a projection objective and an illumination system that includes a temperature compensated polarization-modulating optical element. The temperature compensated polarization-modulating optical element includes a first polarization-modulating optical element of optically active material, the first polarization-modulating optical element having a first specific rotation with a sign. The temperature compensated polarization-modulating optical element includes also includes a second polarization-modulating optical element of optically active material, the second polarization-modulating optical element having a second specific rotation with a sign opposite to the sign of the first specific rotation.

Abstract: Illumination systems for microlithographic projection exposure apparatus, as well as related systems, components and methods are disclosed. In some embodiments, an illumination system includes one or more scattering structures and an optical integrator that produces a plurality of secondary light sources.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a light source to produce projection light beam, and a first and a second diffractive optical element between the light source and a pupil plane of the illumination system. The diffractive effect produced by each diffractive optical element depends on the position of a light field that is irradiated by the projection light on the diffractive optical elements. A displacement mechanism changes the mutual spatial arrangement of the diffractive optical elements. In at least one of the mutual spatial arrangements, which can be obtained with the help of the displacement mechanism, the light field extends both over the first and the second diffractive optical element. This makes it possible to produce in a simple manner continuously variable illumination settings.

Abstract: An EUV lithography system has an EUV beam path and a monitor beam path. The EUV beam path includes a mirror system having plurality of mirror elements, the orientations of which can be changed. The monitor beam path includes a monitor radiation source, a screen and a spatially resolving detector. The mirror system is arranged in the monitor beam path between the monitor radiation source and the screen.

Abstract: An optical hollow waveguide assembly (1) includes an optical hollow waveguide (2) for guiding illumination light (3). The hollow waveguide (2) has a tubular main body (6) with a continuous waveguide cavity (7). The waveguide cavity has an illumination light inlet (8) and an illumination light outlet (9). A cavity inner wall (10) of the waveguide cavity (7) is configured to be highly reflective for the illumination light (3) under grazing incidence. A gas source (12) has a fluid connection (13) to the waveguide cavity (7). The resulting hollow waveguide assembly exhibits a reduced risk of contamination of the hollow waveguide.

Abstract: An optical component for a projection exposure apparatus includes a multiplicity of variably positionable beam-guiding elements which serve as pupil facets. The optical component can be arranged in the beam path of the projection optical unit.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes an optical raster element configured to produce a plurality of secondary light sources located in a system pupil surface. The optical raster element has a plurality of light entrance facets, each being associated with one of the secondary light sources. A beam deflecting device includes a beam deflection array of reflective or transparent beam deflecting elements, each being configured to illuminate a spot on one of the light entrance facets at a position that is variable by changing a deflection angle produced by the beam deflecting element. A control unit is configured to control the beam deflection elements such that variable light patterns assembled from the spots can be formed on at least one of the plurality of light entrance facets.

Abstract: A beam distribution optical unit serves for splitting an incident beam of illumination light into at least two emergent illumination-light beams. The beam distribution optical unit has at least one blazed reflection grating having reflective grating structures. The result is an optical unit in which a plurality of illumination-light beams are efficiently produced from one incident beam of illumination light.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a light source operated in a pulsed manner and a DMD (digital mirror device) or another array of optical elements, which are digitally switchable between two switching positions.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a light source operated in a pulsed fashion and an array of optical elements which are digitally switchable between two switching positions. The array may be produced using MEMS technology.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes an optical integrator having a plurality of light entrance facets each being associated with a secondary light source. A spatial light modulator has a light exit surface and transmit or to reflect impinging projection light in a spatially resolved manner. A pupil forming unit directs projection light on the spatial light modulator. An objective images the light exit surface of the spatial light modulator onto the light entrance facets of the optical integrator. The light exit surface of the optical light modulator includes groups of object areas being separated by areas that are not imaged on the light entrance facets. The objective combines images of the object areas so that the images of the object areas abut on the optical integrator.

Abstract: A measuring system (10) for measuring an imaging quality of an EUV lens (30) includes a diffractive test structure (26), a measurement light radiating device (16) which is configured to radiate measurement light (21) in the EUV wavelength range onto the test structure, a variation device (28) for varying at least one image-determining parameter of an imaging of the test structure that is effected by a lens, a detector (14) for recording an image stack including a plurality of images generated with different image-determining parameters being set, and an evaluation device (15) which is configured to determine the imaging quality of the lens from the image stack.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a light source to produce projection light beam, and a first and a second diffractive optical element between the light source and a pupil plane of the illumination system. The diffractive effect produced by each diffractive optical element depends on the position of a light field that is irradiated by the projection light on the diffractive optical elements. A displacement mechanism changes the mutual spatial arrangement of the diffractive optical elements. In at least one of the mutual spatial arrangements, which can be obtained with the help of the displacement mechanism, the light field extends both over the first and the second diffractive optical element. This makes it possible to produce in a simple manner continuously variable illumination settings.

Abstract: A microlithography optical system includes a projection objective and an illumination system that includes a temperature compensated polarization-modulating optical element. The temperature compensated polarization-modulating optical element includes a first polarization-modulating optical element of optically active material, the first polarization-modulating optical element having a first specific rotation with a sign. The temperature compensated polarization-modulating optical element includes also includes a second polarization-modulating optical element of optically active material, the second polarization-modulating optical element having a second specific rotation with a sign opposite to the sign of the first specific rotation.

Abstract: 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.

Abstract: An EUV lithography system 1 comprises an EUV beam path and a monitor beam path 51. The EUV beam path comprises a mirror system 13, which has a base and a multiplicity of mirror elements 17 having concave mirror surfaces, the orientation of which relative to the base is respectively adjustable. The monitor beam path 51 comprises at least one monitor radiation source 53, a screen 71, the mirror system 13, which is arranged in the monitor beam path 51 between the monitor radiation source 53 and the screen 71, and a spatially resolving detector 77. In this case, each of a plurality of the mirror elements generates an image of the monitor radiation source in an image plane assigned to the respective mirror elements, distances B between the image planes assigned to the mirror elements and the screen have a maximum distance, distances A between each of the plurality of mirror elements and the image plane assigned to it have a minimum distance, and the maximum distance B is less than half of the minimum distance A.

Abstract: Microlithographic illumination system includes individually drivable elements to variably illuminate a pupil surface of the system. Each element deviates an incident light beam based on a control signal applied to the element. The system also includes an instrument to provide a measurement signal, and a model-based state estimator configured to compute, for each element, an estimated state vector based on the measurement signal. The estimated state vector represents: a deviation of a light beam caused by the element; and a time derivative of the deviation. The illumination system further includes a regulator configured to receive, for each element: a) the estimated state vector; and b) target values for: i) the deviation of the light beam caused by the deviating element; and ii) the time derivative of the deviation.

Abstract: A mask for microlithography comprises a substrate; a first pattern area on the substrate, the first pattern area comprising a first pattern extending over a first length in a mask scanning direction and a first width in a direction perpendicular to the mask scan direction; and a second pattern area on the substrate adjacent to the first pattern area in the mask scanning direction, the second pattern area comprising a second pattern extending over a second length in the mask scanning direction and a second width identical to the first width in the direction perpendicular to the mask scan direction.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a pupil forming unit directing light on a spatial light modulator that transmits or reflects impinging light in a spatially resolved manner. An objective images a light exit surface of the spatial light modulator on light entrance facets of an optical integrator so that an image of an object area on the light exit surface completely coincides with one of the light entrance facets. The pupil forming unit and the spatial light modulator are controlled so that the object area is completely illuminated by the pupil forming unit and projection light associated with a point in the object area is at least partially and variably prevented from impinging on the one of the light entrance facets.