Abstract: A method for producing a multilayer coating (17) for reflecting radiation in the soft X-ray or EUV wavelength range on an optical element (8, 9) which is operated at an operating temperature (TOP) of 30° or more, preferably of 100° C. or more, particularly preferably of 150° C. or more, in particular of 250° C. or more, comprising: determining an optical design for the multilayer coating (17) which defines an optical desired layer thickness (nOP dOP) of the layers (17.1, 17.2) of the multilayer coating (17) at the operating temperature (TOP), and applying the layers (17.1, 17.2) of the multilayer coating (17) with an optical actual layer thickness (nB dB) chosen in such a way that a layer thickness change (nOP dOP?nB dB) caused by thermal expansion of the layers (17.1, 17.2) between the coating temperature (TB) and the operating temperature (TOP) is compensated for.

Abstract: An illumination system for EUV microlithography includes an EUV light source which generates EUV illumination light with an etendue that is higher than 0.01 mm2. The EUV light source generates a sequence of EUV light pulses having a pulse sequence frequency. An illumination optics of the illumination system is used to guide the illumination light from the light source to an object field. At least one optical modulation component of the illumination system is preferably modulatable synchronously with the pulse sequence frequency. The result is an illumination system where a homogeneity of an object field illumination is improved.

Abstract: A field facet mirror for an illumination optics of a projection exposure apparatus for EUV microlithography transmits a structure of an object arranged in an object field into an image field. The field facet mirror has a plurality of field facets with reflection surfaces. The arrangement of the field facets next to one another spans a base plane. Projections of the reflection surfaces of at least two of the field facets onto the base plane differ with respect to at least one of the following parameters: size, shape, orientation. A field facet mirror results which can ensure a uniform object field illumination with a simultaneously high EUV throughput.

Abstract: An illumination optical unit for EUV microlithography includes a first optical element having a plurality of first reflective facet elements and a second optical element having a plurality of second reflective facet elements. Each first reflective facet element from the plurality of the first reflective facet elements has a respective maximum number of different positions which defines a set—associated with the first facet element—consisting of second reflective facet elements in that the set consists of all second facet elements onto which the first facet element directs radiation in its different positions during the operation of the illumination optical unit. The plurality of second reflective facet element forms a plurality of disjoint groups, wherein each of the groups and each of the sets contain at least two second facet elements, and there are no two second facet elements of a set which belong to the same group.

Abstract: A component for setting a scan-integrated illumination energy in an object plane of a microlithography projection exposure apparatus is disclosed. The component includes a plurality of diaphragms which are arranged alongside one another with respect to a direction perpendicular to the scan movement and which differ in their form and the position of which can be altered approximately in the scan direction so that a portion of the illumination energy can be vignetted by at least one diaphragm. The form of the individual diaphragm is specifically adapted to the form of the illumination in a diaphragm plane in which the component is arranged. This has the effect that at least parts of the delimiting edges of two diaphragms always differ in the case of an arbitrary displacement of the diaphragms.

Abstract: An illumination optics for EUV microlithography guides an illumination light bundle from a radiation source to an object field with an extension ratio between a longer field dimension and a shorter field dimension, where the ratio is considerably greater than 1. A field facet mirror has a plurality of field facets that set defined illumination conditions in the object field. A following optics downstream of the field facet mirror transmits the illumination light into the object field. The following optics includes a pupil facet mirror with a plurality of pupil facets. The field facets are in each case individually allocated to the pupil facets so that portions of the illumination light bundle impinging upon in each case one of the field facets are guided on to the object field via the associated pupil facet.

Abstract: A projection objective for microlithography is used for imaging an object field in an object plane into an image field in an image plane. The projection objective comprises at least six mirrors of which at least one mirror has a freeform reflecting surface. The ratio between an overall length (T) of the projection objective and an object image shift (dOIS) can be smaller than 12. The image plane is the first field plane of the projection objective downstream of the object plane. The projection objective can have a plurality of mirrors, wherein the ratio between an overall length (T) and an object image shift (dOIS) is smaller than 2.

Abstract: A facet mirror is to be used as a bundle-guiding optical component in a projection exposure apparatus for microlithography. The facet mirror has a plurality of separate mirrors. For individual deflection of incident illumination light, the separate mirrors are in each case connected to an actuator in such a way that they are separately tiltable about at least one tilt axis. A control device, which is connected to the actuators, is configured in such a way that a given grouping of the separate mirrors can be grouped into separate mirror groups that include in each case at least two separate mirrors. The result is a facet mirror which, when installed in the projection exposure apparatus, increases the variability for setting various illumination geometries of an object field to be illuminated by the projection exposure apparatus. Various embodiments of separate mirrors for forming the facet mirrors are described.

Abstract: An illumination optics for microlithography includes an optical assembly for guiding illumination light to an object field to be illuminated in an object plane. The illumination optics can divide an illumination light radiation bundle into a plurality of radiation sub-bundles which are assigned to different illumination angles of the object field illumination. The illumination optics is configured so that at least some of the radiation sub-bundles are superimposed in a superposition plane which is spaced from the object plane and which is not imaged into the object plane in which superposition takes place. This superposition is such that edges of the superimposed radiation sub-bundles coincide at least partially. In some embodiments, a field intensity setting device includes a plurality of adjacent individual diaphragms which at least attenuate illumination light when exposed thereon.

Abstract: In general, in one aspect, the invention features a system that includes an illumination system of a microlithography tool, the illumination system including a first component having a plurality of elements. During operation of the system, the elements direct radiation from a source along an optical path to an arc-shaped object field at an object plane of a projection objective, and at least one of the elements has a curved shape that is different from the arc-shape of the object field.

Abstract: An illumination system is used to illuminate a specified illumination field of an object surface with EUV radiation. The illumination system has an EUV source and a collector to concentrate the EUV radiation in the direction of an optical axis. A first optical element is provided to generate secondary light sources, and a second optical element is provided at the location of these secondary light sources, the second optical element being part of an optical device which includes further optical elements, and which images the first optical element into an image plane into the illumination field. Between the collector and the illumination field, a maximum of five reflecting optical elements are arranged. These optical elements reflect the main beam either grazingly or steeply. The optical axis, projected onto an illumination main plane, is deflected by more than 30° between a source axis portion and a field axis portion.

Abstract: A projection exposure apparatus for microlithography has an illumination system with an EUV light source and an illumination optical unit to expose an object field in an object plane. A projection optical unit images the object field into an image field in an image plane. A pupil facet mirror in a plane of the illumination optical unit that coincides with a pupil plane of the projection optical unit or that is optically conjugate with respect thereto has a plurality of individual facets on which illumination light can impinge. A correction diaphragm is in or adjacent to a pupil plane of the projection optical unit or in a conjugate plane with respect thereto. The correction diaphragm screens the illumination of the entrance pupil of the projection optical unit so that at least some source images assigned to the individual facets of the pupil facet mirror in the entrance pupil of the projection optical unit are partly shaded by one and the same diaphragm edge.

Abstract: An illumination system is used to illuminate a specified illumination field of an object surface with EUV radiation. The illumination system has an EUV source and a collector to concentrate the EUV radiation in the direction of an optical axis. A first optical element is provided to generate secondary light sources, and a second optical element is provided at the location of these secondary light sources, the second optical element being part of an optical device which includes further optical elements, and which images the first optical element into an image plane into the illumination field. Between the collector and the illumination field, a maximum of five reflecting optical elements are arranged. These optical elements reflect the main beam either grazingly or steeply. The optical axis, projected onto an illumination main plane, is deflected by more than 30° between a source axis portion and a field axis portion.

Abstract: The disclosure relates to illumination optical systems for microlithography, such as EUV-microlithography, as well as related systems, components and methods.

Abstract: The disclosure relates to an illumination system for EUV lithography, as well as related elements, systems and methods. In some embodiments, an illumination system includes a first optical element and a second optical element. The first optical element can include a plurality of first facet elements configured so that, when impinged by respective partial beams of radiation, the plurality of first facet elements produce secondary light sources. The second optical element can include a second optical element including a plurality of second facet elements. Each of the plurality of second facet elements can be assigned to at least one of the plurality of first facet elements. The plurality of second facet elements can be configured to be impinged by the radiation via the first optical element.

Abstract: The disclosure relates to illumination systems for projection exposure apparatuses, projection exposure apparatus, and related components, systems and methods. The illumination systems can be configured to be used with wavelengths less than 193 nm.

Abstract: A projection exposure apparatus for microlithography is disclosed. The apparatus can include a radiation source to generate illumination radiation and a reticle holder to receive a reticle in an object plane. The apparatus can further include illumination optics to guide the illumination radiation to an object field, which is to be illuminated, in the object plane. The apparatus can also include a wafer holder to receive a wafer in an image plane and projection optics to image the object field into an image field in the image plane. The radiation source and projection optics can be arranged in separate chambers (e.g., one above the other). The chambers can be separated by a wall. There can be an illumination radiation leadthrough in the wall. In some embodiments, the projection exposure apparatus can guide the illumination radiation with low loss.

Abstract: Collectors are disclosed. The collectors can be for illumination systems with a wavelength ?193 nm, including ?126 nm, and the EUV range. The collectors can serve to receive the light rays emitted from a light source and to illuminate an area in a plane. The collectors can include at least a first mirror shell or a first shell segment as well as a second mirror shell or a second shell segment receiving the light and providing a first illumination and a second illumination in a plane which is located in the light path downstream of the collector. An illumination systems are also disclosed. The illumination systems can be equipped with a collector. Projection exposure apparatuses are also disclosed. The projection exposure apparatuses can include an illumination system. Methods for the manufacture of microstructures by photographic exposure are also disclosed.

Abstract: An illumination system is used to illuminate a specified illumination field of an object surface with EUV radiation. The illumination system has an EUV source and a collector to concentrate the EUV radiation in the direction of an optical axis. A first optical element is provided to generate secondary light sources, and a second optical element is provided at the location of these secondary light sources, the second optical element being part of an optical device which includes further optical elements, and which images the first optical element into an image plane into the illumination field. Between the collector and the illumination field, a maximum of five reflecting optical elements are arranged. These optical elements reflect the main beam either gratingly or steeply. The optical axis, projected onto an illumination main plane, is deflected by more than 30° between a source axis portion and a field axis portion.