Abstract: In a method for characterizing at least one optical component of a projection exposure apparatus (1), an intensity distribution of the illumination radiation (2) is detected in a field plane of the projection exposure apparatus (1) with a measuring device (31) and predicted values of an optical parameter are spatially determined therefrom over at least one predefined surface.

Abstract: Emissions of NOx and/or CO are reduced at the stack by systems and methods wherein a primary fuel is thoroughly mixed with a specific range of excess combustion air. The primary fuel-air mixture is then discharged and anchored within a combustion chamber of a burner. Further, the systems and methods provide for dynamically controlling NOx content in emissions from a furnace by adjusting the flow of primary fuel and of a secondary stage fuel, and in some cases controlling the amount or placement of combustion air into the furnace.

Abstract: The disclosure provides an illumination system of a microlithographic projection device having an image plane, in which a mask can be arranged, and a first object plane, which is optically conjugate to the image plane. A first illumination optical unit illuminates the first object plane with first projection light so that the first projection light has a first illumination angle distribution in the image plane. A second illumination optical unit illuminates a second object plane, which is optically conjugate to the image plane, with second projection light so that the second projection light has a second illumination angle distribution differing from the first illumination angle distribution in the image plane. An optical integrator is arranged exclusively in the light path of the first projection light.

Abstract: An illumination system of a microlithographic projection apparatus includes a spatial light modulator having a modulation surface including a plurality of micromirrors. Each micromirror includes a mirror surface having an orientation that can be changed individually for each micromirror. For at least one of the micromirrors, at least one parameter that is related to the mirror surface is measured. The orientation of the mirror surfaces is controlled depending on the at least one measured parameter. A light pattern is produced on the modulation surface, and an image of the light pattern is formed on an optical integrator that has a plurality of light entrance facets. Images of the light entrance facets are superimposed on a mask.

Abstract: A microlithography illumination system includes a first light source configured to generate pulses of light, a second light source configured to generate further pulses of light offset temporally relative to the pulses of light generated by the first light source, an array of optical elements digitally switchable between first and second switching positions, and a control device to drive the optical elements so that during use the switching position of the optical elements is unchanged while any of the first and second light sources generates a light pulse. In the first switching position of the optical elements, the array couples light pulses generated by the first light source into a common beam path of the illumination system. In the second switching position of the optical elements, the array couples light pulses generated by the second light source into a common beam path of the illumination system.

Abstract: The disclosure provides an illumination system of a microlithographic projection device having an image plane, in which a mask can be arranged, and a first object plane, which is optically conjugate to the image plane. A first illumination optical unit illuminates the first object plane with first projection light so that the first projection light has a first illumination angle distribution in the image plane. A second illumination optical unit illuminates a second object plane, which is optically conjugate to the image plane, with second projection light so that the second projection light has a second illumination angle distribution differing from the first illumination angle distribution in the image plane. An optical integrator is arranged exclusively in the light path of the first projection light.

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 optical unit for a mask inspection system is used with EUV illumination light. A hollow waveguide of the illumination optical unit serves for guiding the illumination light. The hollow waveguide has an entry opening for the illumination light and an exit opening for the illumination light. An imaging mirror optical unit, arranged downstream of the hollow waveguide serves to image the exit opening into an illumination field. This results in an illumination optical unit, the throughput of which is optimized for the EUV illumination light.

Abstract: An illumination system of a microlithographic projection apparatus includes a spatial light modulator having a modulation surface including a plurality of micromirrors. Each micromirror includes a mirror surface having an orientation that can be changed individually for each micromirror. For at least one of the micromirrors, at least one parameter that is related to the mirror surface is measured. The orientation of the mirror surfaces is controlled depending on the at least one measured parameter. A light pattern is produced on the modulation surface, and an image of the light pattern is formed on an optical integrator that has a plurality of light entrance facets. Images of the light entrance facets are superimposed on a mask.

Abstract: An optical system of a microlithographic projection exposure apparatus designed for an operating wavelength of at least 150 nm. In one disclosed aspect, the optical system includes an element (11, 21) producing an angular distribution for light incident during the operation of the optical system and a fly's eye condenser (200, 400, 500) which includes two arrangements (210, 220, 410, 420, 510, 520) following one another in the light propagation direction and made of beam-deflecting optical elements (211-213, 221-223, 411-413, 421-423, 511-513, 521-523), which produce a multiplicity of optical channels. No optical element with refractive power is arranged in the beam path between the element (11, 21) producing an angular distribution and the fly's eye condenser (200, 400, 500).

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 optical system for a microlithographic projection exposure apparatus and a microlithographic exposure method are disclosed. In an embodiment an optical system for a microlithographic projection exposure apparatus includes at least one mirror arrangement having a plurality of mirror elements which are displaceable independently of each other for altering an angular distribution of the light reflected by the mirror arrangement. The optical system also includes at least one manipulator downstream of the mirror arrangement in the light propagation direction. The manipulator has a raster arrangement of manipulator elements so that light incident on the manipulator during operation of the optical system is influenced differently in its polarization state and/or in its intensity in dependence on the incidence location.

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 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.

Abstract: An optical system of a microlithographic projection exposure apparatus designed for an operating wavelength of at least 150 nm. In one disclosed aspect, the optical system includes an element (11, 21) producing an angular distribution for light incident during the operation of the optical system and a fly's eye condenser (200, 400, 500) which includes two arrangements (210, 220, 410, 420, 510, 520) following one another in the light propagation direction and made of beam-deflecting optical elements (211-213, 221-223, 411-413, 421-423, 511-513, 521-523), which produce a multiplicity of optical channels. No optical element with refractive power is arranged in the beam path between the element (11, 21) producing an angular distribution and the fly's eye condenser (200, 400, 500).

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.