Abstract: A catadioptric projection objective for imaging a pattern arranged in the object plane (102) of the projection objective into the image plane (104) of the projection objective has a catadioptric first objective part (105) having at least one concave mirror (106), and a dioptric second objective part (108) in which there is situated a pupil surface (111) near the image. At least one concave lens (140, 145) with a concave surface (140?, 145?) directed towards the pupil surface (111) is arranged in a near zone (160) of the pupil surface. There are no lenses with a strongly curved concave surface directed towards the image plane between the pupil surface and the image plane. Such projection objectives can be produced in a way which saves material in conjunction with good optical correction, and are relatively insensitive to production-induced deviations from the ideal design.

Abstract: A method of determining materials of lenses contained in an optical system of a projection exposure apparatus is described. First, for each lens of a plurality of the lenses, a susceptibility factor KLT/LH is determined. This factor is a measure of the susceptibility of the respective lens to deteriorations caused by at least one of lifetime effects and lens heating effects. Then a birefringent fluoride crystal is selected as a material for each lens for which the susceptibility factor KLT/LH is above a predetermined threshold. Theses lenses are assigned to a first set of lenses. For these lenses, measures are determined for reducing adverse effects caused by birefringence inherent to the fluoride crystals.

Abstract: A projection exposure lens has an object plane, optical elements for separating beams, a concave mirror, an image plane, a first lens system arranged between the object plane and the optical elements for separating beams, a second double pass lens system arranged between the optical elements for separating beams and the concave mirror, a third lens system arranged between the optical elements for separating beams and the image plane. The second lens system has a maximum of five lenses.

Abstract: A projection exposure lens has an object plane, optical elements for separating beams, a concave mirror, an image plane, a first lens system arranged between the object plane and the optical elements for separating beams, a second double pass lens system arranged between the optical elements for separating beams and the concave mirror, a third lens system arranged between the optical elements for separating beams and the image plane. The second lens system has a maximum of five lenses.

Abstract: A projection objective of a microlithographic projection exposure apparatus has a correction device which can correct photoinduced imaging errors without optical elements having to be removed for this purpose. The correction device includes a first optical element and a second optical element, whose surface facing the first optical element is provided with a local surface deformation for improving the imaging properties of the projection objective. In a wall, which seals an intermediate space formed between the first optical element and the second optical element, an opening is provided through which the intermediate space can be filled with a fluid. By modifying the refractive index of the fluid adjacent to the surface, the effect of the surface deformation can be modified in a straightforward way.

Abstract: A catadioptric projection objective which images a pattern arranged in an object plane of the projection objective into the image plane of the projection objective while generating a real intermediate image has a catadioptric objective part having at least one concave mirror and a beam deflecting device and also a dioptric objective part. The imaging system has a system diaphragm having a variable diaphragm diameter for variably limiting the cross section of the radiation passing through the projection objective. This system diaphragm is arranged in the catadioptric objective part, preferably in direct proximity to the concave mirror. The invention enables a projection objective with a simple construction.

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 comprises: a first objective part for imaging the pattern provided in the object plane into a first intermediate image; a second objective part for imaging the first intermediate imaging into a second intermediate image; a third objective part for imaging the second intermediate imaging directly onto the image plane; wherein a first concave mirror having a first continuous mirror surface and at least one second concave mirror having a second continuous mirror surface are arranged upstream of the second intermediate image; pupil surfaces are formed between the object plane and the first intermediate image, between the first and the second intermediate image and between the second intermediate image and the image plane; and all concave mirrors are arranged optically remote from a pupil surface.

Abstract: A purely refractive projection objective suitable for immersion microlithography is designed as a single-waist system with five lens groups, in the case of which a first lens group with negative refractive power, a second lens group with positive refractive power, a third lens group with negative refractive power, a fourth lens group with positive refractive power and a fifth lens group with positive refractive power are provided. A constriction site of narrowest constriction of the beam bundle lies in the region of the waist. A waist distance AT exists between the object plane and the constriction site X. The condition AT/L?0.4 holds for a distance ratio AT/L between the waist distance AT and an object-image distance L of the projection objective. Embodiments of inventive projection objectives reach very high numerical apertures NA>1.1 in conjunction with a large image field and are distinguished by a compact overall size and good correction of the lateral chromatic aberration.

Abstract: A catadioptric projection objective for imaging a pattern arranged on the object plane of the projection objective, on the image plane of the projection objective, comprising: a first objective part for imaging an object field in a first real intermediate image; a second objective part for producing a second real intermediate image with the radiation coming from the first objective part; and a third objective part for imaging the second real intermediate image on the image plane; wherein at least one of the objective parts is a catadioptric objective part with a concave mirror, and at least one of the objective parts is a refractive objective part and a folding mirror is arranged within this refractive objective part in such a way that a field lens is arranged between the folding mirror and an intermediate image which is closest to the folding mirror.

Abstract: A catadioptric projection objective is used to project a pattern arranged in an object plane of the projection objective into an image plane of the projection objective with the formation of at least one real intermediate image and has an image-side numerical aperture NA>0.7. The projection objective comprises an optical axis and at least one catadioptric objective part that comprises a concave mirror and a first folding mirror. There are a first beam section running from the object plane to the concave mirror and a second beam section running from the concave mirror to the image plane. The first folding mirror is arranged with reference to the concave mirror in such a way that one of the beam sections is folded at the first folding mirror and the other beam section passes the first folding mirror without vignetting, the first beam section and the second beam section crossing one another in a cross-over region.

Abstract: A microlithographic projection exposure apparatus contains an illumination system (12) for generating projection light (13) and a projection lens (20; 220; 320; 420; 520; 620; 720; 820; 920; 1020; 1120) with which a reticle (24) that is capable of being arranged in an object plane (22) of the projection lens can be imaged onto a light-sensitive layer (26) that is capable of being arranged in an image plane (28) of the projection lens. The projection lens is designed for immersion mode, in which a final lens element (L5; L205; L605; L705; L805; L905; L1005; L1105) of the projection lens on the image side is immersed in an immersion liquid (34; 334a; 434a; 534a). A terminating element (44; 244; 444; 544; 644; 744; 844; 944; 1044; 1144) that is transparent in respect of the projection light (13) is fastened between the final lens element on the image side and the light-sensitive layer.

Abstract: A catadioptric projection lens for imaging a pattern arranged in an object plane onto an image plane, preferably while creating a real intermediate image, including a catadioptric first lens section having a concave mirror and a physical beamsplitter having a beamsplitting surface, as well as a second lens section that is preferably refractive and follows the beamsplitter, between its object plane and image plane. Positive refractive power is arranged in an optical near-field of the object plane, which is arranged at a working distance from the first optical surface of the projection lens. The beamsplitter lies in the vicinity of low marginal-ray heights, which allows configuring projection lenses that are fully corrected for longitudinal chromatic aberration, while employing small quantities of materials, particularly those materials needed for fabricating their beamsplitters.