Abstract: A method and lithography device addressing the problem in projection optics of pupil apodization which leads to imaging defects. As here proposed, the illumination system is configured to illuminate the mask inhomogeneously. As a result, inhomogeneities in reflectivity caused by the mask itself are at least partly counteracted. This compensation not only makes the apodization over the pupil become more symmetric but also makes the intensity variation smaller overall.

Abstract: Another approach to decrease the resolution is to introduce an immersion liquid having high refractive index into the gap that remains between a final lens element on the image side of the projection objective and the photoresist or another photosensitive layer to be exposed. Projection objectives that are designed for immersion operation and are therefore also referred to as immersion objective may reach numerical apertures of more than 1, for example 1.3 or 1.4. The term “immersion liquid” shall, in the context of this application, relate also to what is commonly referred to as “solid immersion”. In the case of solid immersion, the immersion liquid is in fact a solid medium that, however, does not get in direct contact with the photoresist but is spaced apart from it by a distance that is only a fraction of the wavelength used. This ensures that the laws of geometrical optics do not apply such that no total reflection occurs.

Abstract: A catadioptric projection objective for imaging a pattern provided in an object plane of the projection objective onto an image plane of the projection objective has a first, refractive objective part for imaging the pattern provided in the object plane into a first intermediate image; a second objective part including at least one concave mirror for imaging the first intermediate imaging into a second intermediate image; and a third, refractive objective part for imaging the second intermediate imaging onto the image plane; wherein the projection objective has a maximum lens diameter Dmax, a maximum image field height Y?, and an image side numerical aperture NA; wherein COMP1=Dmax (Y??NA2) and wherein the condition COMP1<10 holds.

Abstract: The invention relates to a projection exposure system, in particular for micro-lithography. The projection exposure system according to the invention comprises a light source for producing light in the EUV region. The projection exposure system further comprises a first optical system for illuminating a mask by the light of the light source and a second optical system for imaging the mask on a component. At least one polarization-optical element is disposed on the beam path between the light source and the component.

Abstract: There is provided a projection objective for a projection exposure apparatus that has a primary light source for emitting electromagnetic radiation having a chief ray with a wavelength?193 nm. The projection objective includes an object plane, a first mirror, a second mirror, a third mirror, a fourth mirror; and an image plane. The object plane, the first mirror, the second mirror, the third mirror, the fourth mirror and the image plane are arranged in a centered arrangement around a common optical axis. The first mirror, the second mirror, the third mirror, and the fourth mirror are situated between the object plane and the image plane. The chief ray, when incident on an object situated in the object plane, in a direction from the primary light source, is inclined away from the common optical axis.

Abstract: An apparatus (10) for microlithographic projection exposure, which includes: an optical system (18) for imaging mask structures (16) onto a surface (21) of a substrate (20) by projecting the mask structures (16) with imaging radiation (13), the optical system (18) being configured to operate in the EUV and/or higher frequency wavelength range, and various structure defining a measurement beam path (36) for guiding measurement radiation (34), the measurement beam path (36) extending within the optical system (18) such that the measurement radiation (34) only partially passes through the optical system (18) during operation of the apparatus (10).

Abstract: One problem of projection optics concerns pupil apodization which leads to imaging defects. As here proposed, the illumination system is configured to illuminate the mask inhomogeneously. As a result, inhomogeneities in reflectivity caused by the mask itself are at least partly counteracted. This compensation not only makes the apodization over the pupil become more symmetric but also makes the intensity variation smaller overall.

Abstract: The present invention relates to an illumination system for microlithography, especially for wavelengths ?193 nm, especially preferably for EUV lithography for illuminating a field in a field plane with at least one optical integrator which splits up a light bundle emitted by a light source into a plurality of light channels each having a light intensity, characterized in that a filter is provided in the light path from the light source to the field plane, with the filter comprising filter elements which are configured in such a way that the light intensity of at least one light channel is reduced in the light path after the filter element.

Abstract: The disclosure concerns a projection objective, which can include an object plane in which an object field is formed, an entry pupil, a mirrored entry pupil (RE) in a mirrored entry pupil plane obtained by mirroring the entry pupil (VE) at the object plane, an image plane, an optical axis, at least a first mirror and a second mirror. The projection objective can have a negative back focus of the entry pupil, and a principal ray originating from a central point of the object field and traversing the objective from the object plane to the image plane can intersect the optical axis in at least one point of intersection, wherein the geometric locations of all points of intersection lie between the image plane and the mirrored entry pupil plane.

Abstract: This document provides methods and materials related to treating orthostatic hypotension and/or postural tachycardia syndrome. For example, methods and materials for using a composition containing 3,4-diaminopyridine, 4-aminopyridine, or both to treat patients with orthostatic hypotension, postural tachycardia syndrome, or both orthostatic hypotension and postural tachycardia syndrome are provided.

Abstract: A focusing-device for the radiation from a light source (2) is provided with a collector mirror (1, 1?) which is arranged in a mount (24) and collects the light, in virtual or real terms, from the light source (2) at the second focus (200). The collector mirror (1, 1?) is displaceably connected to the mount (24) via a bearing in such a way that its optical properties remain at least approximately the same even in the event of temperature changes.

Abstract: The disclosure concerns a projection objective, which can include an object plane in which an object field is formed, an entry pupil, a mirrored entry pupil (RE) in a mirrored entry pupil plane obtained by mirroring the entry pupil (VE) at the object plane, an image plane, an optical axis, at least a first mirror and a second mirror. The projection objective can have a negative back focus of the entry pupil, and a principal ray originating from a central point of the object field and traversing the objective from the object plane to the image plane can intersect the optical axis in at least one point of intersection, wherein the geometric locations of all points of intersection lie between the image plane and the mirrored entry pupil plane.

Abstract: A catadioptric projection objective for imaging a pattern provided in an object plane of the projection objective onto an image plane of the projection objective has a first, refractive objective part for imaging the pattern provided in the object plane into a first intermediate image; a second objective part including at least one concave mirror for imaging the first intermediate imaging into a second intermediate image; and a third, refractive objective part for imaging the second intermediate imaging onto the image plane; wherein the projection objective has a maximum lens diameter Dmax, a maximum image field height Y?, and an image side numerical aperture NA; wherein COMP1=Dmax/(Y?·NA2) and wherein the condition COMP1<10 holds.

Abstract: A microlithographic projection exposure apparatus comprises a projection objective which images an object onto an image plane and has a lens with a curved surface. In the projection objective there is a liquid or solid medium which directly adjoins the curved surface over a region which is usable for imaging the object. The projection exposure apparatus also has an adjustable manipulator for reducing an image field curvature which is caused by heating of the medium during the projection operation.

Abstract: There is provided a collector system. The collector system includes a first collector mirror and a second collector mirror. The first collector mirror receives EUV light from a light source at a first aperture angle via a first beam path, and reflects the EUV light at a second aperture angle along a second beam path. The first aperture angle is larger than or substantially equal to the second aperture angle. The second mirror receives the EUV light from the first mirror at the second aperture angle. The collector is an oblique mirror type normal incidence mirror collector system.

Abstract: There is provided a collector system. The collector system includes a first collector mirror and a second collector mirror. The first collector mirror receives EUV light from a light source at a first aperture angle via a first beam path, and reflects the EUV light at a second aperture angle along a second beam path. The first aperture angle is larger than or substantially equal to the second aperture angle. The second mirror receives the EUV light from the first mirror at the second aperture angle. The collector is an oblique mirror type normal incidence mirror collector system.

Abstract: A microlithographic projection exposure apparatus comprises a projection objective which images an object onto an image plane and has a lens with a curved surface. In the projection objective there is a liquid or solid medium which directly adjoins the curved surface over a region which is usable for imaging the object. The projection exposure apparatus also has an adjustable manipulator for reducing an image field curvature which is caused by heating of the medium during the projection operation.

Abstract: A projection objective for imaging a pattern provided in an object plane of the projection objective onto an image plane of the projection objective suitable for microlithography projection exposure machines has a plurality of optical elements transparent for radiation at an operating wavelength of the projection objective. At least one optical element is a high-index optical element made from a high-index material with a refractive index n?1.6 at the operating wavelength.

Abstract: There is provided an illumination system for microlithography with wavelengths?193 nm that includes a primary light source, a first optical component, a second optical component, an image plane, and an exit pupil. The first optical component transforms the primary light source into a plurality of secondary light sources that are imaged by the second optical component in the exit pupil. The first optical element and the second optical element are reflective. The first optical component includes a first optical element having a plurality of first raster elements that are imaged into the image plane, producing a plurality of images being superimposed, at least partially, on a field in the image plane. The first optical component includes a collector unit and a second optical element having a plurality of second raster elements.

Abstract: There is provided an illumination system for microlithography with wavelengths ?193 nm. The illumination system includes a primary light source, a first optical component, a second optical component, an image plane, and an exit pupil. The first optical component transforms the primary light source into a plurality of secondary light sources that are imaged by the second optical component in the exit pupil. The first optical component includes a first optical element having a plurality of first raster elements that are imaged into the image plane, producing a plurality of images being superimposed at least partially on a field in the image plane. The second optical component comprises a first optical system that includes at least a third field mirror with positive optical power and a second optical system that includes at least a second field mirror with positive optical power.