Abstract: A projection exposure method for exposing a radiation-sensitive substrate with at least one image of a pattern of a mask is provided in which an illumination field of the mask is illuminated by illumination radiation with an operating wavelength ? that was provided by an illumination system.

Abstract: A catadioptric projection objective for images an object field onto an image field via imaging radiation. The projection objective includes at least one reflective optical component and a measuring device. The reflective optical component, during the operation of the projection objective, reflects a first part of the imaging radiation and transmits a second part of the imaging radiation. The reflected, first part of the imaging radiation at least partly contributes to the imaging of the object field. The transmitted, second part of the imaging radiation is at least partly fed to a measuring device. This allows a simultaneous exposure of the photosensitive layer at the location of the image field with the imaging radiation and monitoring of the imaging radiation with the aid of the measuring device.

Abstract: A mirror, in particular for a microlithographic projection exposure apparatus, has an optical effective surface and includes a substrate (11, 61, 71, 81, 91), a reflection layer system (16, 66, 76, 86, 96) for reflecting electromagnetic radiation impinging on the optical effective surface (10a, 60a, 70a, 80a, 90a), an electrode arrangement (13, 63, 73, 83) composed of a first material having a first electrical conductivity, the electrode arrangement being provided on the substrate, and a mediator layer (12, 62, 72, 82, 92) composed of a second material having a second electrical conductivity. The ratio between the first electrical conductivity and the second electrical conductivity is at least 100. The mirror also includes at least one compensation layer (88) which at least partly compensates for the influence of a thermal expansion of the electrode arrangement (83) on the deformation of the optical effective surface (80a).

Abstract: The disclosure relates to a microlithography projection exposure system having optical corrective elements configured to modify the imaging characteristics, as well as related systems and component.

Abstract: An attenuation filter is configured to define attenuation of the intensity of ultraviolet radiation with a specified working wavelength from a wavelength range of 150-370 nm according to a specifiable local distribution in a projection lens of a microlithographic projection exposure apparatus. The attenuation filter has a substrate and an absorption layer on the substrate. The substrate is sufficiently transparent at the working wavelength. The absorption absorbs incident ultraviolet radiation of the working wavelength according to the specifiable local distribution at different locations of a used area to varying degrees. The attenuation filter reduces or avoids a thermally induced wavefront variation error in the ultraviolet radiation which has passed through the attenuation filter owing to locally varying heating of the substrate, which is caused by the absorption of the ultraviolet radiation that varies locally over the substrate. A thickness of the substrate is less than 100 ?m.

Abstract: A microlithographic projection exposure apparatus includes a projection lens that is configured for immersion operation. For this purpose an immersion liquid is introduced into an immersion space that is located between a last lens of the projection lens on the image side and a photosensitive layer to be exposed. To reduce fluctuations of refractive index resulting from temperature gradients occurring within the immersion liquid, the projection exposure apparatus includes heat transfer elements that heat or cool partial volumes of the immersion liquid so as to achieve an at least substantially homogenous or at least substantially rotationally symmetric temperature distribution within the immersion liquid.

Abstract: The disclosure relates to an optical module with first and second components, a supporting structure and an anticollision device. The first component is supported by the supporting structure and is arranged adjacent to and at a distance from the second component to form a gap. The supporting structure defines a path of relative movement, on which the first and second components move in relation to one another under the influence of a disturbance, a collision between collision regions of the first and second components occurring if the anticollision device is inactive. The anticollision device includes a first anticollision unit on the first component, which produces a first field, and a second anticollision unit on the second component, which is assigned to the first anticollision unit and produces a second field.

Abstract: An optical component for coupling out an individual output beam from a collective output beam includes a plurality of radiation-reflecting regions which are grouped in such a way that regions of the same group serve for guiding different partial beams of the individual output beam to the same scanner.

Abstract: Microlithography projection objectives for imaging into an image plane a pattern arranged in an object plane are described with respect to suppressing false light in such projection objectives.

Abstract: The invention relates to a projection exposure apparatus for semiconductor lithography, comprising at least one manipulator for reducing image aberrations, wherein the manipulator has at least two optical elements that can be positioned relative to one another, wherein at least one of the optical elements is spatially dependent in terms of its effect on an optical wavefront passing therethrough such that a local phase change of a wavefront propagating in the optical system is produced in the case of a relative movement of the optical elements against one another. Here, the spatially dependent effect of the at least one optical element can be set in a reversible dynamic manner.

Abstract: A projection lens (50) for a microlithographic projection exposure apparatus (10) includes a plurality of optical elements (M1-M8) for imaging mask structures (28) onto a surface (34) of a substrate (36) by way of projecting the mask structures using imaging radiation (14) that travels along a used beam path. At least one of the optical elements (M8) is formed with an opening (56) and the projection lens has a measurement beam path (66) extending through the opening.

Abstract: A catadioptric projection objective for images an object field onto an image field via imaging radiation. The projection objective includes at least one reflective optical component and a measuring device. The reflective optical component, during the operation of the projection objective, reflects a first part of the imaging radiation and transmits a second part of the imaging radiation. The reflected, first part of the imaging radiation at least partly contributes to the imaging of the object field. The transmitted, second part of the imaging radiation is at least partly fed to a measuring device. This allows a simultaneous exposure of the photosensitive layer at the location of the image field with the imaging radiation and monitoring of the imaging radiation with the aid of the measuring device.

Abstract: An attenuation filter is configured to define attenuation of the intensity of ultraviolet radiation with a specified working wavelength from a wavelength range of 150-370 nm according to a specifiable local distribution in a projection lens of a microlithographic projection exposure apparatus. The attenuation filter has a substrate and an absorption layer on the substrate. The substrate is sufficiently transparent at the working wavelength. The absorption absorbs incident ultraviolet radiation of the working wavelength according to the specifiable local distribution at different locations of a used area to varying degrees. The attenuation filter reduces or avoids a thermally induced wavefront variation error in the ultraviolet radiation which has passed through the attenuation filter owing to locally varying heating of the substrate, which is caused by the absorption of the ultraviolet radiation that varies locally over the substrate. A thickness of the substrate is less than 100 um.

Abstract: A catadioptric projection objective has a multiplicity of lenses and at least one concave mirror, and also two deflection mirrors in order to separate a partial beam path running from the object field to the concave mirror from the partial beam path running from the concave mirror to the image field. The deflection mirrors are tilted relative to the optical axis of the projection objective about tilting axes running parallel to a first direction (x-direction). The first deflection mirror is arranged in optical proximity to a first field plane and the second deflection mirror is arranged in optical proximity to a second field plane, which is optically conjugate with respect to the first field plane. A displacement device for the synchronous displacement of the deflection mirrors is provided. The deflection mirrors have different local distributions of their reflection properties in first and second reflection regions, respectively.

Abstract: A method of providing a catadioptric projection includes: providing a first partial objective for imaging an object field onto a first real intermediate image; providing a second partial objective for imaging the first real intermediate image onto a second real intermediate image, in which the second partial objective includes a concave mirror; providing a third partial objective for imaging the second intermediate image onto an image field, the third partial objective including an aperture stop; providing a first folding mirror and a second folding mirror; and providing an antireflection coating onto a surface of at least one lens that is directly adjacent to the concave mirror or that is separate from the concave mirror by a single lens, in which the antireflection coating is designed to have reflectivity of less than 0.2% for a wavelength between 150 nm and 250 nm and for an angle-of-incidence range between 0° and 30°.

Abstract: The invention relates to a projection exposure apparatus for semiconductor lithography, comprising an illumination system for illuminating a mask arranged on a movable mask stage, and comprising a projection lens for imaging the mask onto a semiconductor substrate, wherein at least one means is present for at least partly decoupling at least parts of the illumination system and/or of the projection lens from the influence of pressure fluctuations in the medium surrounding the projection lens or the illuminated system, the pressure fluctuations being attributed to movements of the mask stage during the operation of the apparatus.

Abstract: A projection exposure apparatus (10) for microlithography has a measuring system (50) for measuring an optical element of the projection exposure apparatus. The measuring system (50) includes an irradiation device (54), which is configured to radiate measuring radiation (62) in different directions (64) onto the optical element (20), such that the measuring radiation (62) covers respective optical path lengths (68) within the optical element (20) for the different directions (64) of incidence, a detection device (56), which is configured to measure, for the respective directions (64) of incidence, the respective optical path lengths covered by the measuring radiation (62) in the optical element (20), and an evaluation device, which is configured to determine a spatially resolved distribution of refractive indices in the optical element (20) by computed-tomographic back projection of the respective measured path lengths with respect to the respective directions of incidence.

Abstract: A projection lens is disclosed for imaging a pattern arranged in an object plane of the projection lens into an image plane of the projection lens via electromagnetic radiation having an operating wavelength ? from the extreme ultraviolet range. The projection lens includes a multiplicity of mirrors having mirror surfaces arranged in a projection beam path between the object plane and the image plane so that a pattern of a mask in the object plane is imagable into the image plane via the mirrors. A first imaging scale in a first direction running parallel to a scan direction is smaller in terms of absolute value than a second imaging scale in a second direction perpendicular to the first direction. The projection lens also includes a dynamic wavefront manipulation system for correcting astigmatic wavefront aberration portions caused by reticle displacement.

Abstract: A catadioptric projection objective for images an object field onto an image field via imaging radiation. The projection objective includes at least one reflective optical component and a measuring device. The reflective optical component, during the operation of the projection objective, reflects a first part of the imaging radiation and transmits a second part of the imaging radiation. The reflected, first part of the imaging radiation at least partly contributes to the imaging of the object field. The transmitted, second part of the imaging radiation is at least partly fed to a measuring device. This allows a simultaneous exposure of the photosensitive layer at the location of the image field with the imaging radiation and monitoring of the imaging radiation with the aid of the measuring device.

Abstract: A method for manufacturing an integrated circuit includes scanning a wafer with respect to a catadioptric projection objective and imaging a pattern on a mask onto a wafer while scanning the wafer. The imaging includes illuminating the mask with radiation; imaging, using the radiation, the pattern into a first intermediate image, the first intermediate image to a second intermediate image, and the second intermediate image into an image field arranged in an image surface where the wafer is arranged; and, manipulating one or more of optical elements while scanning the wafer to reduce errors in the image at the image field. A concave mirror arranged in a region of a pupil surface reflects the radiation. The projection objective also includes mirrors to deflect the radiation from the object field towards the concave mirror and to deflect the radiation from the concave mirror towards the image field.