WO2003093904A1 - Projection lens comprising an extremely high aperture - Google Patents

Abstract

The invention relates to a purely refractive projection lens comprising an extremely large aperture. Said projection lens is embodied as a double-convexity system having one convexity on the object side, one convexity on the image side, and a throat (7) which is located between the same. The system diaphragm (5) is arranged at a distance from the image plane in the convexity on the image side. A negative group (LG5) is arranged between the throat and the system diaphragm in the region of the divergent radiation, said negative group having an effective swell with a concave side oriented towards the image plane. The system is characterised by a high numeric aperture, few chromatic aberrations and a compact, material-saving structure.

Description

 Description Projection lens with the highest aperture

The invention relates to a projection lens for imaging one arranged in the object plane of the projection lens

Patterns in the image plane of the projection lens with ultraviolet light of a predetermined working wavelength.

Photolithographic projection lenses have been used for the manufacture of semiconductor devices and other finely structured components for several decades. They serve to project patterns of photomasks or graticules, which are also referred to below as masks or reticles, onto an object coated with a light-sensitive layer with the highest resolution on a reduced scale.

In order to produce ever finer structures of the order of magnitude 100 nm or less, an attempt is made to enlarge the numerical aperture (NA) of the projection objectives on the image side beyond the currently achievable values in the range of NA = 0.8 or above. In addition, ever shorter working wavelengths of ultraviolet light are used, preferably wavelengths of less than 260 nm, for example 248 nm, 193 nm, 157 nm or less. At the same time, attempts are being made to meet the increasing imaging requirements with purely refractive, dioptric systems, which are advantageous in terms of structure and production in comparison to catadioptric systems. With wavelengths becoming shorter and shorter, however, there are only a few sufficiently transparent materials available, the imaging constants of which are relatively close to one another. This makes partial achromatization and even more complete achromatization of the projection objectives, ie largely avoiding or reducing chromatic aberrations, problematic. In particular it is difficult to provide high aperture systems with sufficient small chromatic aberrations. Furthermore, the dimension of the projection lens grows in all three spatial directions with increasing aperture and additionally necessary improved imaging qualities with a constant object and image field. In particular, the increase in volume of the optical lens material makes such projection lenses more expensive than the gain in structure width reduction.

The object of the invention is to create a projection lens which is distinguished by a high numerical aperture on the image side and improved chromatic correction. In particular, a material-saving, compact structure should be made possible.

This object is achieved by a projection objective with the features of claim 1. Advantageous further developments are specified in the dependent claims. The wording of all claims is incorporated by reference into the content of the description.

According to one aspect of the invention, a projection lens for imaging a pattern arranged in the object plane of the projection lens into the image plane of the projection lens with ultraviolet light of a predetermined working wavelength has a multiplicity of optical elements which are arranged along an optical axis and one which is arranged at a distance in front of the image plane system diaphragm. The projection lens is designed as a purely refractive (dioptric) one-waist system with an abdomen close to the object, an abdomen close to the image and an intermediate waist. In the area of the waist, the jet diameter can be significantly smaller than the maximum jet diameter in the area of one of the bellies, the jet diameter in the waist area, for example, less than 50% of the maximum beam diameter can be. A negative group is arranged in a region of divergent radiation between the waist and the system diaphragm, which has an effective curvature with a concave side directed towards the image.

A "negative group" in this sense is a lens group with an overall negative refractive power, wherein the lens group can comprise one or more lenses. The effective curvature causes the negative group as a whole to be curved against the beam path. This curvature can be characterized by a curved surface, the The effective curvature of the lens (or the curvature surface) is characterized by a curvature radius r _c , which is calculated as follows for a lens whose entrance surface has the radius n and whose exit surface has the radius r ₂ :

1 / r _c = 1 / (2 ^* r-ι) + 1 / (2 ^* r ₂ ). (1)

If the negative group consists of two or more lenses, the effective curvature of the group is calculated as follows:

1 / r _c = 1 / (n ^* rι) + 1 / (n ^* r ₂ ) + 1 / (n ^* r ₃ ) + 1 / (n ^* r ₄ ) + .... (2)

where n is the number of surfaces.

The effective concave curvature in the image, together with the divergence of the radiation in the area of the lenses, causes high incidence angles to occur, in particular on the exit sides of the one or more lenses of the negative group. These are particularly effective for the correction of high-order image errors, in particular for the aperture-dependent correction (over-correcting) of monochromatic image errors in the image field zone and the image field edge. In order to be able to manufacture the projection lens particularly economically, it is necessary to minimize its use of materials. This is achieved on the one hand by the limitation to one waist and on the other hand by an ever increasing field load on the system. It is only through the invention that it is possible to achieve an effective correction of all monochromatic errors with only one waist at such a high field load. In the examples shown, the field load has already increased massively, but the limit has not yet been reached. The correction options of the group in connection with higher overall asphericity lead to a further increase in the field load and thus a future reduction in costs of the lithographic projection lenses. It is clear that the aperture of the projection lens and the field loading of the lens could not be driven so high without the targeted use of aspheres already described. The negative group can at least partially create corrective functions that would otherwise only be possible by providing an additional waist. Compared to such conventional three-bellied systems, a significant reduction in the overall length, the diameter, and a reduction in the volume of material required for production and thus a substantial reduction in the total price can be achieved in projection lenses according to the invention. By increasing the field load and combining it with only one waist, the longitudinal color error can be significantly reduced. This means that even with a very high aperture, there is no need to use CaF ₂ at around 193 nm in the largest lenses around the diaphragm.

In a further development, the negative group comprises at least one lens with negative refractive power and a concave surface directed towards the image. The negative refractive power can also be distributed over a plurality of successive lenses of this type having a negative refractive power, the centers of curvature for the exit surfaces on the image side each being on the image side. Here is at Using only one or two such lenses with a negative refractive power enables a particularly material-saving, compact structure. If two lenses are strung together, it is advantageous if the refractive power of the first lens on the object side is stronger than that of the subsequent lens on the image side of the group. These negative lenses can be designed as negative meniscus lenses.

It has turned out to be favorable if the negative group is arranged in a central region between a location of the narrowest constriction of the waist and the system cover. Accordingly, the negative group acts on medium-sized bundles of rays and can have moderate diameters. Lenses with negative refractive power are naturally in the area of the waist. Furthermore, there should be at least one large lens with negative refractive power for spherical correction in the area of the diaphragm. The negative group presented is particularly advantageous in the ascending region of the second waist. The lenses in the waist often have a bend, especially in the center of the waist, which obey the principle of minimal beam deflection in order to induce as few aberrations as possible. The task of the crushing lenses at the waist is first to redirect a convergent tuft to a divergent tuft. This, in conjunction with the large bellies, allows the system to image field correction or Petzval correction.

Another task is the skillful correction of aberration contributions from the bellies with positive refractive power. The negative group in the first part of the second abdomen differs fundamentally from the inner negative waist lenses in terms of deflection. The goal is not a tuft forming with balanced loads on the entry and exit side, but a deliberately asymmetrical load. The divergent tuft enters the lens with moderate deflection and then exits under extreme stress. This highly stressed surface allows the desired correction effect. The characteristic bulging surfaces of the outer negative lenses of the waist bulge towards the center of the waist. These external lenses advantageously "violate" the principle of minimal deflection. The object-side surface of the first negative waist lens and the image-side surface of the last waist lens, in conjunction with increased angular stress, have a particularly good effect on image correction. The more important of these two waist lenses is that This lens is followed by the second belly.This lens, on the other hand, is the image-side outer surface, which is the decisive medium-high-stress area.Without the advantageous negative group presented in the ascending area of the second waist, it would have to carry important parts of the correction of the field- and aperture-dependent image correction - However, despite massive aspherization, unacceptable zone contributions regarding field and aperture remain for crooked tufts.

This problem is solved by the negative group in the ascending area of the second waist, with the help of a suitable adjustment of the mean angular load on the exit surface of the last waist lens with medium tuft variation and the high angular load on the exit surface or exit surfaces of the negative lens or lenses in ascending area of the second waist with little tuft variation. The corrective contributions for the oblique spherical aberrations then complement each other so well that the highest field loads and the highest apertures, such as NA = 0.95, can be achieved with the smallest wavefront deviation.

Suitable conditions can be achieved in particular if for the parameters: A = maximum angular load in gas of the image-side exit surface of a lens of the negative group in the ascending area of the second abdomen in degrees.

B = maximum angular load in gas of the image-side exit surface of the last lens with negative refractive power in the lens waist in degrees.

C = ratio of edge jet height of A to maximum coma jet height of A

D = ratio of the edge jet height of B to the maximum coma jet height of B, the condition: A / B> C / D applies

The angular load can e.g. can be quantified by the corresponding maximum incidence angle of the radiation (in gas).

The characteristic vaulted surfaces of the negative group in the first part of the second belly bulge to form the picture. The apex of the overall characterizing curvature surface of the negative group should be in the range between approx. 30% and approx. 70%, in particular between approx. 40% and approx. 60% of the axial distance between the area of the narrowest constriction of the waist and the system cover.

The effective curvature of the negative group can be adjusted to optimize the system properties. The effective curvature preferably has a curvature radius r _c , whose ratio r _c / DB to the diaphragm diameter DB is in the range between approximately 0.8 and approximately 2.2, preferably in the range between approximately 1.0 and approximately 2.0 , in particular in the range between approx. 1.1 and approx. 1.9.

In preferred embodiments, the projection objective in the area of the system diaphragm has an essentially symmetrical structure with biconvex positive lenses and negative with respect to a plane of symmetry perpendicular to the optical axis Meniscus lenses. This essentially symmetrical structure makes it possible to achieve a good correction state with lower overall asphericity even with large openings. The plane of symmetry is preferably close to the system aperture. It is possible to leave this symmetrical structure in the direction of increasing or increasing the refractive power of the negative lens behind the diaphragm and a reduction in refractive power of the negative lens in front of the diaphragm. This symmetrical arrangement makes it possible to manage with less aspherization effort. If the testing and manufacturing possibilities of more complex and stronger asphericities are improved, the symmetry can be changed at the expense of the negative lens upstream of the aperture, i.e. lower refractive power or substitution by asphericity in the overall system. The large negative lens after the aperture should always have the same orientation of the effective curvature as the curvature of the negative group in the ascending area between the waist and the system aperture.

The system diaphragm in the sense of this application is the area closer to the image plane in which either the main beam of the image intersects the optical axis or locations are available where the

The height of a coma beam corresponds to the height of an edge beam. A diaphragm (aperture diaphragm) for delimiting and possibly adjusting the aperture used can be arranged in the area of the system diaphragm. The invention makes it possible to achieve an effective correction of all errors with only one waist. The

Negative groups can at least partially assume the function of a second waist, as is the case with conventional ones

Three-bellied systems is available. Compared to such three-bellied systems, a significant reduction in the overall length, a reduction in the length of the Manufacturing required material volume and a reduction in color errors can be achieved.

It has proven to be advantageous if a negative meniscus lens with a concave surface on the object side is arranged directly in front of the system aperture and a negative meniscus lens with a concave surface on the image side is arranged directly behind the system aperture. The system diaphragm can be freely accessible between them, for example in order to attach an adjustable diaphragm to limit the beam diameter. This aperture can also be moved axially when opening and closing. An advantageous embodiment is also provided by spherical diaphragms in connection with these single-waist systems, since the diaphragm curvature of preferred embodiments can still be used for this.

The symmetry can continue far into the object-side and image-side close range of the system diaphragm. For example, a positive / negative doublet with a biconvex lens on the object side and a subsequent negative meniscus lens with a concave surface on the object side can be arranged directly in front of the system bezel and a doublet constructed in mirror image to the rear of the system bezel. In some embodiments, the doublets on the object or image side are still framed by biconvex lenses.

The systems can be set up so that all transparent optical elements are made of the same material. This applies in particular to 248nm, a pure quartz glass solution is technically advisable. In an embodiment designed for a working wavelength of 193 nm, synthetic quartz glass suitable for 193 nm is also used for all lenses. However, one or more near-image lenses or lenses with increased radiation and Settings load (dipole, quadrupole with a small sigma) consist of another material, e.g. CaF ₂ . Embodiments for 157 nm, in which all lenses are made of calcium fluoride or combined with another fluoride crystal material, are also possible. Combinations of several different materials are also possible, for example to make it easier to correct color errors or to reduce compaction or lens heating. For example, at 193 nm, the synthetic quartz glass can be replaced by a crystal material, for example calcium fluoride, in some or all of the lenses.

Within the scope of the invention, high-aperture projection objectives, in particular also purely refractive projection objectives, are possible, in which the numerical aperture NA> 0.85 on the image side. It is preferably at least 0.9.

Preferred projection objectives are distinguished by a number of favorable constructive and optical features, which alone or in combination with one another are conducive to the suitability of the objective for high-resolution microlithography.

At least one aspherical surface is preferably arranged in the area of the system cover. Preferably, several surfaces with aspheres come closely behind the diaphragm. It can also be advantageous if the last optical surface before the system diaphragm and the first optical surface after the system diaphragm are aspherical. In particular, opposite aspherical surfaces with curvature pointing away from the diaphragm can be provided here. The high number of aspherical surfaces in the area of the system aperture is favorable for the correction of the spherical aberration and has a favorable effect on the setting of the isoplanasia. Furthermore, it can be favorable if at least one positive meniscus lens with a concave surface on the object side is arranged between the waist and the system panel in the vicinity of the waist. Instead of such a meniscus lens, several, for example two, successive lenses of this type can be provided.

Embodiments are particularly advantageous in which the effective curvature changes between the waist and the system diaphragm in this order at least between two lenses, the effective curvature of the first lens being on the object side and the effective curvature of the immediately following lens being on the image side. Two successive positive lenses of the respective curvatures are preferably provided. A change in the position of the center of curvature of the effective curvature thus takes place in the area between these lenses or lens groups.

A plurality of negative lenses are preferably arranged one after the other in the region of the waist, in preferred embodiments there are at least two, preferably three negative lenses. These bear the main burden of the Petzval correction and part of the correction of the crooked tufts.

At the object-side entrance of the system when entering the first belly, at least two negative lenses are advantageous in order to widen the beam coming from the object. Three or more such negative lenses are preferred. With high entrance apertures, it is favorable if at least one aspherical surface is provided on at least one of the first lenses. Each of the input-side negative lenses preferably has at least one aspherical surface. Regardless of the refractive power of the lenses, it is advantageous if a wafer-side aspherization takes place for the first two lenses in a single-lens lens. The closer the first asphere is to the reticle, the higher the tuft separation and the more effective the aspherization. The asphere on the front of the second lens is then also very close to the reticle, but already has very different tuft cross-sections, so that the pair of aspheres can complement each other ideally and also has an optimal effect. As a caution, however, it should be mentioned that the tuft cross-sections are particularly small and this leads to the requirement to produce particularly smooth aspherical lenses.

A lens group with a strong positive refractive power, which represents the first belly of the beam guidance, preferably follows behind this input group. Embodiments are particularly advantageous in which the effective curvature changes between the reticle and waist, at least between two lenses, the effective curvature of the first lens being on the object side and the effective curvature of the immediately following lens being on the image side. Two successive positive lenses of the respective curvatures are preferably provided. A change in the position of the center of curvature of the effective curvature thus takes place in the area between these lenses or lens groups. In this group, at least one meniscus lens with positive refractive power and concave surfaces on the image side can be favorable in the area of still large beam heights in the vicinity of the object plane, since this contributes to the Petzval relief of the lens.

The foregoing and other features emerge from the claims and also from the description and the drawing, the individual features being implemented individually and in groups in the form of sub-combinations in one embodiment of the invention and in other fields, and advantageous as well protective designs can represent. Fig. 1 is a lens section through an embodiment of a refractive projection lens that for 193nm

Working wavelength is designed

FIG. 2 is a lens section through an embodiment of a refractive projection lens that is suitable for 157 nm

Working wavelength is designed;

3 is a lens section through an embodiment of a refractive projection lens designed for a 193 nm working wavelength; and

FIG. 4 is a lens section through an embodiment of a refractive projection lens that is suitable for 157 nm

Working wavelength is designed.

In the following description of the preferred embodiment, the term “optical axis” denotes a straight line through the centers of curvature of the spherical optical components or through the axes of symmetry of aspherical elements. Directions and distances are described as image-side, wafer-side or image-wise when they are in the direction of the If the image plane or the substrate to be exposed there is directed and as the object side, reticle side or object side, if they are directed towards the object in relation to the optical axis, the object is a mask (reticle) with the pattern of an integrated circuit in the examples , but it can also be a different pattern, for example a grid. In the examples, the image is formed on a wafer serving as a substrate and serving with a photoresist layer, but other substrates are also possible, for example elements for liquid crystal displays or substrates for optical gratings.

1 shows a characteristic structure of a purely refractive reduction objective 1 according to the invention. It serves to display a pattern of a reticle or the like arranged in an object plane 2 in an image plane 3 conjugated to the object plane on a reduced scale without obscurations or shadowing in the image field, for example in scale 4 1. It is a rotationally symmetrical one-waist system, whose lenses are along a perpendicular to

Object and image plane standing optical axis 4 are arranged and form an object-side abdomen 6, an image-side abdomen 8 and an intermediate waist 7. The system diaphragm 5 is in the near-image area of large beam diameters.

The lenses can be divided into several successive lens groups with specific properties and functions. A first lens group LG1 following the object plane 2 at the input of the projection lens has negative refractive power overall and serves to expand the beam coming from the object field. A subsequent second lens group LG2 with an overall positive refractive power forms the first belly 6 and brings the beam together again in front of the subsequent waist 7. In the area of the waist 7 there is a third lens group LG3 with negative refractive power. This is followed by a fourth lens group LG4 consisting of positive meniscus lenses with positive refractive power, which is followed by a fifth lens group LG5 consisting of negative meniscus lenses with negative refractive power. The subsequent lens group LG6 with positive refractive power leads the radiation to the system aperture 5. Behind this is the seventh and last lens group LG7, which mainly consist of individual lenses with positive refractive power and makes the main contribution to the generation of the very high image-side numerical aperture of NA = 0.93.

The first lens group LG1 opens with three negative lenses 11, 12, 13, which in this order comprises a negative lens 11 with an aspherical entry side, a negative meniscus lens 12 with an image-side center of curvature and an aspherical entry side and a negative meniscus lens 13 with an object-side center of curvature and an aspherical exit side. In the present high entrance aperture, at least one aspherical surface should be provided on at least one of the first two lenses 11, 12 in order to limit the generation of aberrations in this area. Preferably, as in the present example, an aspherical surface (at least) is provided on each of the three negative lenses.

The second lens group LG2, with a small air gap behind the last lens 13 of the first lens group LG1, has a biconvex positive lens 14, another biconvex positive lens 15, a positive meniscus lens 16 with a center of curvature on the image side, another positive lens 17 with an almost flat exit side, a positive meniscus lens 18 with the center of curvature of the surfaces on the image side and three further meniscus lenses 19, 20, 21 of the same direction of curvature. The entry side of the lens 15 and the exit side of the last meniscus lens 21 reaching the waist are aspherical. As a result, there is an asphere in the area of the waist. This second lens group LG2 represents the first belly 6 of the objective. A special feature is the positive meniscus lens 16 arranged at the largest diameter, the centers of curvature of which lie on the image side. This lens group is used primarily for Petzval correction, distortion and telecentricity correction and image field correction outside of the main sections. The third lens group LG3 consists of three negative meniscus lenses 22, 23, 24, the interfaces of which are each spherical. This lens group bears the main burden of correcting the curvature of the image and is designed in such a way that, despite the high system aperture of NA = 0.93, the maximum incidence angle of the rays hitting the lens surfaces is below approx. 60 ° or the sine of the incidence angle is each below 0.85 lies. The first negative lens 22 of the third group is preferably a strongly biconcave lens, so that the main waist 7 opens with strongly curved surfaces.

The fourth lens group LG4 following the waist 7 consists of two positive meniscus lenses 24, 25 with object-side concave faces, the exit side of the meniscus lens 24 on the input side being aspherical, the other surfaces being spherical. In other embodiments, only a single positive meniscus of corresponding curvature can be provided at this point.

The subsequent fifth lens group LG5 also has two meniscus lenses 27, 28, but these each have negative refractive power and the concave surfaces are directed toward the image field 3. If necessary, only a negative meniscus can be provided at this point, the center of curvature of which lies on the wafer side. Such a group with at least one lens with negative refractive power is a central correction element for the function of the one-waist system in order to elegantly correct off-axis image errors. In particular, this enables a compact design with relatively small lens diameters.

Due to the overall negative refractive power, the fifth lens group LG5 is also referred to here as a negative group. Each of the negative meniscus lenses 27, 28 can be characterized by a curved surface shown in dashed lines, which runs centrally between the entrance and exit surface and whose radius r _c is defined according to Eq. (1 ) can be calculated. The curvature area of the entire negative group LG5 shown in dash-dotted lines, which according to Eq. (2) can be calculated, just like the curvature surfaces of the individual lenses 27, 28, has a concave side facing the image surface 3 or a center of curvature lying on the image side. It lies in the middle between the curvature surfaces of the individual lenses 27, 28. The negative group is arranged approximately in the middle between the area of the narrowest constriction of the waist 7 and the system diaphragm 5 in the area of diverging beam bundles. The curvature directed against the beam path causes high incidence angles of the emerging radiation to occur on the exit surfaces of the two negative meniscus lenses, in particular on the exit surface of the first meniscus 27, which have a strong correction effect, in particular for the monochromatic, strongly field and pupil-dependent ones image defects. In other embodiments, a single negative lens with a concave concave surface toward the image can also be provided at this point. Negative groups with three or more lenses are also possible. If there are several lenses, each of the lenses does not have to be a negative lens as long as the overall refractive power is negative. Both too strong and too weak curvatures of the curvature surface should be avoided in order to allow a compromise between the optimal correction effect and large incidence angles that are manageable in terms of production technology. The ratio between the radius r _c of the dotted curve area of the lens group LG5 and the diaphragm diameter should be between approximately 0.8 and 2.2 and in this embodiment is approximately 1.035 (total value).

It is also particularly important that that following the waist 7

Entrance area of the second abdomen 8 a change in the position of the centers of curvature between menisci of the fourth lens group

LG4 and the lenses of the fifth lens group LG5 takes place. Thereby can be achieved that oblique spherical aberration can be smoothed with an extreme aperture.

The sixth lens group LG6 begins with a sequence of biconvex positive lenses 29, 30. Their collecting effect is absorbed again by a subsequent, strongly bent negative meniscus 31. This negative meniscus in front of the aperture 5 is bent towards the aperture, that is to say it has a concave surface on the object side. The corresponding counterpart sits directly behind the panel. This negative meniscus 32 is also bent to the diaphragm, it has a concave surface on the image side. This is followed by two large biconvex positive lenses 33, 34 with the largest diameter. This is followed by two positive meniscus lenses 35, 36 concave to the image plane, a weakly negative meniscus lens 37, a weak positive lens with a slightly curved entry side and an almost flat exit side, and a plane-parallel end plate 39.

The structure of the second belly, which is relatively elongated and slowly widens from the waist to the largest diameter, is constructed in the area of the system diaphragm 5 essentially symmetrically to a plane of symmetry which is perpendicular to the optical axis and is close to the system diaphragm. The negative meniscus lenses 31, 32, the positive lenses 30, 33 enclosing these and the biconvex lenses 29 and 34 arranged outside these doublets correspond almost mirror images. The central region of the second abdomen around the diaphragm thus contains only biconvex lenses as positive lenses and only curved lenses as negative lenses menisci. A meniscus-shaped air space is formed in each of the doublets 30, 32 and 32, 33.

The first belly contains a weakly positive meniscus lens 19 in the descending area. This forms thicker with the following Meniscus lens 20 a strongly bent, open air space. In the airspace that follows there is a less arched, outwardly closing air meniscus. This enables an improved shell matching in the sagittal and tangential cut. At the same time, the angular load in the region of the concave entry surface of the negative lens 22 can thereby also be kept under the aperture load. The Petzval correction is mainly performed by the lenses in the waist area in connection with the large bellies. Still, a single waist is enough. In the case of the lens 27 of negative refractive power, which is curved in the image direction, particular care must be taken to ensure good centering, since a slight decentration would immediately result in coma contributions on the highly stressed exit surface.

Table 1 summarizes the specification of the design in a known manner in tabular form. Column 1 gives the number of a refractive or otherwise distinguished surface, column 2 the radius r of the surface (in mm), column 3 the distance d of the surface from the following surface (in mm), which is referred to as thickness, column 4 the material of the optical components and column 5 the refractive index or the refractive index of the material of the component, which follows the entry surface. Column 6 shows the usable free radii or half the free diameter of the lenses (in mm).

In the embodiment, twelve of the surfaces, namely surfaces 2, 4, 7, 10, 23, 31, 36, 41, 43, 45, 48 and 50 are aspherical. Table 2 shows the corresponding aspherical data, whereby the aspherical surfaces are calculated according to the following rule:

p (h) = [((1 / r) h ² ) / (1 + SQRT (1- (1 + K) (1 / r) ² h ² )] + C1 * h ⁴ + C2 * h ⁶ +. ... The reciprocal (1 / r) of the radius indicates the surface curvature and h the distance of a surface point from the optical axis. Thus p (h) gives the so-called arrow height, ie the distance of the surface point from the surface vertex in the z direction, ie in the direction of the optical axis. The constants K, C1, C2, ... are shown in Table 2.

The optical system 1 which can be reproduced with the aid of this information is designed for a working wavelength of approximately 193 nm, at which the synthetic quartz glass used for all lenses has a refractive index n = 1,56029. The numerical aperture on the image side is 0.93. The lens has a length (distance between image plane and object plane) of 1342mm, the field size is 10.5 * 26.0mm.

This creates a projection lens that works at a working wavelength of 193nm, can be produced with the help of conventional techniques for lens production and coatings and allows resolution of structures well below 100nm and is very well corrected. This becomes clear from low transverse aberration values and a wavefront RMS value of a maximum of 3.3mλ at 193nm over all image heights.

Another embodiment is explained with reference to FIG. 2 and Tables 3 and 4, which is designed for a working wavelength of 157 nm and is constructed exclusively from calcium fluoride components. The type and sequence of the lenses corresponds to the embodiment according to FIG. 1. The corresponding lenses and lens groups are therefore identified by the same reference numerals. The lens 100 is somewhat more compact with a length of 1000mm, has a numerical aperture of 0.93 and a field size of 12 * 17mm. A maximum wavefront RMS value of 3mλ across all image heights proves one excellent correction condition of the lens. The example shows that the basic principles of the invention can easily be transferred to lenses for other wavelengths.

A further embodiment 300, which is designed for a working wavelength of 193 nm, is explained with reference to FIG. 3 and tables 5 and 6. With the exception of the penultimate lens 38 near the image plane 3, all lenses are made of synthetic quartz glass. The positive lens 38 is made of calcium fluoride and has a positive effect on transverse color errors, while at the same time producing little undesirable longitudinal color errors. The type and sequence of the lenses essentially corresponds to the embodiment according to FIG. 1, the difference being that the positive meniscus lens 36 there, which is concave in the image direction, is split here into two positive meniscus lenses 36, 36 'with the same sense of curvature. The corresponding lenses and lens groups are identified by the same reference numerals. The objective 300 has an overall length of 1250 mm, a numerical aperture of NA = 0.9 and a field size of 10.5 x 26 mm. The maximum wavefront RMS value is between 5 and 6mλ.

4 and tables 7 and 8, another embodiment designed for 157 nm working wavelength is one

Projection lens 400 explained, in which all lenses are made of calcium fluoride. The crystallographic <111> axes of most or all of the lenses are essentially parallel to the optical axis. The type and sequence of the lenses largely corresponds to the embodiment according to FIG. 1, which is why corresponding lenses and lens groups are designated by the same reference numerals. With an overall length of approx. 1069mm and a field size of 6.0 x 22mm, a numerical aperture of NA = 0.95 is achieved. On maximum wavefront RMS value of approx.2.6mλ over all image heights proves an excellent correction state of the lens. The lenses 13, 15, 16, 18, 21, 24, 26, 28, 30, 33, 35 and 36 are rotated by 60 ° around the optical axis relative to the other lenses in order to achieve a correction of birefringence effects caused by the intrinsic birefringence of calcium fluoride can be caused. This measure can also be provided in the embodiment according to FIG. 2. Tables 9 and 10 show the design data of a comparable projection lens with NA = 0.95, which is calculated for a working wavelength of 193nm. If embodiments with <100> -oriented crystal lenses are provided, they are always mixed with <1 reoriented lenses. The relative rotation of <100> lenses that is suitable for compensation is approximately 45 °, whereas it is approximately 60 ° for <111> lenses. In principle, good compensation can be achieved if lenses with comparable optical paths and comparable incidence angles within the material are rotated in pairs in a planned manner.

TABLE 1 (Shs2003)

FRESH NUMBER 1/2 FREE

AREA RADIEN THICK GLASSES 193.304 nm DIAMETER

0 0. 000000000 33. 600000000 L710 0. 99998200 56. 080

1 0. 000000000 2. 116348742 L710 0. 99998200 64. 111

2 543769. 142501049AS 8. 000000000 SI02HL 1. 56028895 64.830

3 161.64131585 4. 159723042 HE193 0. 99971200 67.531

4 218. 691761237AS 8. 400000000 SI02HL 1. 56028895 69. 959

5 219.026045883 37.232327077 HE193.0.99971200 70.564

6-126. 273541233 9.059812069 SI02HL 1.56028895 71.879

7 590,000664984AS 5. 888594676 HE193 0. 99971200 91.812

8,874. 341541676 45. 211384116 SI02HL 1,56028895 98. 202

9-198. 096216449 0. 750325389 HE193 0. 99971200 103.786

10 946.848097810AS 38.538214934 SI02HL 1.56028895 123.489

11 -425. 263923111 1. 158522801 HE193 0. 99971200 125.867

12 350. 163434277 30. 488033825 SI02HL 1. 56028895 134. 676

13 1009. 701801617 1. 197549469 HE193 0. 99971200 134. 221

14 286.135356357 98.148093037 SI02HL 1. 56028895 134.698

15 19301. 429695110 0. 700000000 HE193 0. 99971200 123. 374

16 272,045958073 31,009665217 SI02HL 1,56028895 116,140

17 737. 805495222 0. 700000000 HE193 0. 99971200 111. 526

18 250. 056020156 17th, 945571560 SI02HL 1,56028895 104,536

19 331.911514310 0. 700000000 HE193 0. 99971200 99.743

20 254. 183348934 45. 167991817 SI02H 1. 56028895 97. 168

21 168th, 278221248 12th, 633486164 HE193 0th 99971200 75th 317th

22 333., 410550457 8., 000000000 SI02HL 1., 56028895 73., 766

23 305. 673163674AS 33., 620359548 HE193 0. 99971200 69.745

24-126. , 882359261 8th, 400000000 SI02HL 1st, 56028895 68th, 517

25 623., 561065898 22. .920166250 HE193 0., 99971200 69., 269

26-159. , 640135295 21st, 959811493 SI02HL 1st, 56028895 69th, 579

27 612., 121329616 25. .136797688 HE193 0., 99971200 79., 613

28 -256. , 899270677 16. .106811172 SI02HL 1. .56028895 82. .648

29-6721. , 059689803 10. .198456701 HE193 0., 99971200 95. .151

30-759. , 091077253 33.505555154 SI02HL 1. .56028895 98. .551

31-373. .512212393AS 2. .955259188 HE193 0. .99971200 110. .248

32-482. .275268598 42, .142366706 SI02HL 1,. 56028895 113. .540

33 -167. .944569801 24, .912342267 HE193 0. .99971200 117. .230

34 352, .644000465 12, .417917014 SI02HL 1. .56028895 140, .307

35 239, .800147366 38. .495163859 HE193 0. .99971200 139, .720

36 919. .430222419AS 12. .380604737 SI02HL 1. .56028895 142, .518

37 415. .408472297 13, .298822306 HE193 0. .99971200 148. .485

38 448. .474261455 47 .786431536 SI02HL 1. .56028895 160 .368

39 -130 .870981174 0 .700000000 HE193 0. .99971200 162 .101

40 549. .477937127 77 .507833077 SI02HL 1, .56028895 175, .924

41 -411. .968607019AS 30 .091104049 HE193 0 .99971200 176 .606

42 -264 .054542030 15 .750000000 SI02HL 1 .56028895 176 .112

43 -528. .210359924AS 37 .000000000 HEI93 0. .99971200 186 .586

44 0 .000000000 -10 .000000000 HE193 0 .99971200 183 .991

45 435 .061723432AS 15 .750000000 SI02HL 1 .56028895 198 .802

46 280 .349256994 17 .105701219 HE193 0 .99971200 193 .492

47 322 .068458373 94 .193714724 SI02HL 1 .56028895 197 .207

48 -987 .718496827AS 1 .636340795 HE193 0 .99971200 196 .856

49 335 .441022838 82 .947217201 SI02HL 1 .56028895 188 .622

50 -1114 .388548306AS 1 .270418444 HE193 0 .99971200 185 .311

51 160 .565830600 40 .174196562 SI02HL 1 .56028895 132 .555

52 202 .910977254 1 .342289784 HE193 0 .99971200 122 .679

53 157 .797608135 61 .229633415 ΞI02HL 1 .56028895 114 .327

54 535 .601426702 12 .273585235 HE193 0 .99971200 94 .469

55 15736 .124930284 15 .585688667 SI02HL 1 .56028895 82 .958

56 394 .939976545 3 .776081840 HE193 0 .99971200 66 .876

57 316 .842290121 22 .015913317 SI02HL 1 .56028895 60 .946

58 7602 .251381444 2 .700000000 L710 0 .99998200 48 .241

59 0 .000000000 3 .150000000 SI02HL 1 .56028895 40 .032

60 0 .000000000 9 .000000000 71Ü 0 .99998200 37 .593

61 0 .000000000 0 .000000000 1. .00000000 14 .020 TABLE 2

AREA NO. AREA NO. 31 AREA NO. 45

K 0. .0000 K 0. .0000 K 0.0000

Cl 1., 22433248e- -008 Cl 1., 22715232e- -008 Cl -3.73975169e- -009

C2 9., 17630275e- -012 C2 -5. .90002335e- -013 C2 -3.74336974e- -015

C3 5th, 91043068e- -016 C3 -1,, 03677463e- -017 C3 9.45872960e- -019

C4 -2. , 47816893e- -019 C4 1, .00008208e- -022 C4 -1.44091264e- -024

C5 3. .41011256e- -023 C5 1.75475591e- -026 C5 1.88129553e- -028

C6 -2. .42906864e- -027 C6 -6,, 61198967e- -031 C6 2.31885357e- -033

C7 -7.26295145e- -038

AREA NO. AREA NO. 36 AREA NO. 48

K 0.0000 K 0.0000 K 0., 0000

Cl 2.09935818e-007 Cl 3.01531517e-009 Cl -4. , 13086555e- -010

C2 -1.58583859e-011 C2 -4.91017017e-014 C2 3. .90501705e- -014

C3 -7.02615456e-016 C3 2.75994489e-019 C3 3., 91619841e- -020

C4 3.85802113e-019 C4 2.00585563e-023 C4 3., 21475780e- -024

C5 -7.10886225e-023 C5 -1.33495290e-027 C5 1. .41056342e- -028

C6 7.34912873e-027 C6 7.55261132e-032 C6 7., 14264851e- -034

C7 -3.35590933e-031 C7 -3.14630848e-037 C7 1, .33303621e- -038

AREA NO. AREA NO. 41 AREA NO. 50

K 0.0000 K 0.0000 K 0.0000

Cl 6.30425513e-009 Cl -3.34727519e-010 Cl 8.02621332e-010

C2 -3.91904384e-013 C2 -1.54638784e-014 C2 1.98373377e-014

C3 -1.31611782e-017 C3 -2.56886946e-019 C3 1.35524355e-022

C4 -2.73217947e-021 C4 2.42822109e-025 C4 -1.48469224e-024

C5 1.92288995e-029 C5 -1.00499822e-030

C5 -3.04177451e-025 C6 7.09209045e-033 C6 -1.45678875e-033

C6 6.68937241e-029 C7 5.08658073e-038

C7 -3.22999413e-033

AREA NO. 10 AREA NO. 43

K 0 .0000 K 0.0000

Cl 4., 51583031e- -009 Cl -6.26438O92e-01O

C2 1. .37702459e- -013 C2 -2.42562722e-015

C3 -6, .06055882e- -018 C3 -1.54495891e-019

C4 -2,, 53779695e- -022 C4 -1.83563042e-024

C5 -3, .73570196e- -027 C5 4.03910963e-029

C6 1, .13076924e -030 C6 2.69828997e-033

C7 -3, .82690442e- -035 C7 -1.10606501e-037

AREA NO. 23

K 0.0000

Cl 7.72459905e-008

C2 3.04280743e-012

C3 2.31066672e-016

C4 4.78460943e-021

C5 4.57773509e-024

C6 -5.03222417e-028

C7 5.93537498e-032 TABLE 3 (Shs2004)

FRESH NUMBER 1/2 FREE

AREA RADIEN THICK GLASSES 157.629nm DIAMETER

0 0. 000000000 25. 017498240 N2V157 1.00031429 41.617

1 0. 000000000 1. 905032434 N2V157 1,00031429 47. 527

2 19166. 139614900AS 5. 960085409 CAF2V157 1.55929035 48. 157

3 119. 172116093 3. 094631417 N2V157 1,00031429 50. 106

4 160. 220213679AS 6. 254374560 CAF2V157 1.55929035 51. 869

5 162.519152248 27. 782451972 N2V157 1.00031429 52. 305

6 -94. 077615349 6. 711100917 CAF2V157 1.55929035 53.364

7 434. 801298224AS 4. 386889894 N2V157 1,00031429 67. 969

8 645.264518232 33.749703361 CAF2V157 1.55929035 72.538

9 -148. 333939508 0.521197880 N2V157 1.00031429 76.917

10 709.275977518AS 29. 000976049 CAF2V157 1.55929035 91.242

11 -317. 503191065 0. 562186502 N2V157 1.00031429 93. 166

12 259. 994970434 20. 919102516 CAF2V157 1.55929035 99. 645

13,776. 574450968. 791803254 N2V157 1,00031429 99,389

14 215. 152145251 73. 117973823 CAF2V157 1.55929035 99.739

15 20868. 347899500 0.521197880 N2V157 1.00031429 91.408

16 202. 493483250 23. 070977801 CAF2V157 1.55929035 86. 145

17 558.418132627 0.521197880 N2V157 1.00031429 82.759

18 186.405556634 13. 439476629 CAF2V157 1.55929035 77.613

19 267., 922416674 0.521197880 N2V157 1,00031429 74,394

20 200.469246207 33.723938177 CAF2V157 1.55929035 72.415

21 125., 811608898 9. 365001399 N2V157 1.00031429 55., 894

22 248., 201572583 5. 956547200 CAF2V157 1.55929035 54.715

23 223 .381908745AS 25th, 172315656 N2V157 1,00031429 51st, 710

24-94. , 453554360 6th, 254374560 CAF2V157 1.55929035 50th, 681

25 485. .764221114 17th, 150487522 N2V157 1,00031429 51st, 201

26-117. .021217251 16., 344741038 CAF2V157 1.55929035 51., 440

27 453 .448396924 18. .745918625 N2V157 1,00031429 58. .835

28-192. .539933332 12., 040746634 CAF2V157 1.55929035 61., 189

29 -10110, .942296700 7. .631352005 N2V157 1,00031429 70. .434

30 -598, .476704330 24. .995144443 CAF2V157 1.55929035 73. .019

31 -277, .690546428AS 2. .270348155 N2V157 1,00031429 81, .569

32 -357, .341411711 31. .502092471 CAF2V157 1.55929035 83. .988

33 -124 .901240251 18, .757658255 N2V157 1,00031429 86, .879

34 262 .323405524 9, .339597466 CAF2V157 1.55929035 103 .686

35 178 .666624180 28 .718074096 N2V157 1,00031429 103 .248

36 686 .201269935AS 9 .311366752 CAF2V157 1.55929035 105 .517

37 309 .588340572 9 .899187354 N2V157 1,00031429 109 .811

38 334 .272397140 35 .656478162 CAF2V157 1.55929035 119 .166

39 -969 .269108454 0 .543015101 N2V157 1,00031429 120 .560

40 408 .715545997 57 .937117409 CAF2V157 1.55929035 131 .252

41 -306 .960999184AS 22 .291849608 N2V157 1,00031429 131 .758

42 -196 .797761340 11 .726952300 CAF2V157 1.55929035 131 .415

43 -394 .026784416AS 27 .549030800 N2V157 1,00031429 139 .222

44 0 .000000000 -7 .445684000 N2V157 1,00031429 137 .237

45 324 .234131088AS 11 .726952300 CAF2V157 1.55929035 148 .288

46 208 .898767751 12 .784071759 N2V157 1,00031429 144 .316

47 239 .964906784 70 .883531850 CAF2V157 1.55929035 147 .077

48 -736 .057578242AS 0 .747525039 N2V157 1,00031429 146 .792

49 249 .829910804 61 .833878347 CAF2V157 1.55929035 140 .681

50 -825 .134407817AS 1 .050234898 N2V157 1,00031429 138 .269

51 119 .514360013 29 .939342632 CAF2V157 1.55929035 98 .761

52 151 .480856759 1 .047402614 N2V157 1,00031429 91 .482

53 117 .647396280 45 .612524461 CAF2V157 1.55929035 85 .201

54 398 .984860293 9 .163549260 N2V157 1,00031429 70 .387

55 10414 .727506900 11 .628662517 CAF2V157 1.55929035 61 .739

56 294 .280794199 2 .821757461 N2V157 1,00031429 49 .745

57 237 .014551128 16 .417043400 CAF2V157 1.55929035 45 .331

58 5516 .098537170 2 .010334680 N2V157 1,00031429 35 .814

59 0 .000000000 2 .345390460 CAF2V157 1.55929035 30 .321

60 0 .000000000 6 .701115600 N2V157 1,00031429 28 .554

61 0 .000000000 10 .404 TABLE 4

AREA NO. AREA NO. 31 AREA NO. 45

K 0.0000 K 0.0000 K 0. .0000

Cl 4.04200750e-008 Cl 3.00166168e-008 Cl -9. , 04760702e- -009

C2 3.81876586e-011 C2 -2.58415596e-012 C2 -1. , 63991553e- -014

C3 5.03315092e-015 C3 -8.33331517e-017 C3 7th, 44005317e- -018

C4 -3.49627521e-018 C4 1.36287634e-021 C4 -2. , 09009335e- -023

C5 8.55465831e-022 C5 4.56615511e-025 C5 4., 81547907e- -027

C6 -1.10162987e-025 C6 -3.21288704e-029 C6 1,. 07329470e- -031

C7 -6. .06561304e- -036

AREA NO. AREA NO. 36 AREA NO.

K 0.0000 K 0.0000 K 0. .0000

Cl 5.00885457e-007 Cl 7.42096101e-009 Cl -1. , 01554668e- -009

C2 -6.73594057e-011 C2 -2.14890363e-013 C2 1. .70305715e- -013

C3 -5.63021479e-015 C3 2.10259884e-018 C3 2. .95803828e- -019

C4 5.25874660e-018 C4 2.93924925e-022 C4 4. .48800481e- -023

C5 -1.72712950e-021 C5 -3.44512052e-026 C5 3. .60194072e- -027

C6 3.18784558e-025 C6 3.42432345e-030 C6 3. .09218205e- -032

C7 -2.59898831e-029 C7 -2.42014198e-035 C7 1, .11798441e- -036

AREA NO. AREA NO. 41 AREA NO. 50

K 0., 0000 K 0. .0000 K 0.0000

Cl 1., 63223882e- -008 Cl -8. , 35434016e- -010 Cl 1.93111104e-009

C2 -1. , 63813024e- -012 C2 -6. .91469747e- -014 C2 8.65128317e-014

C3 -1. , 08828380e- -016 C3 -2. , 02033656e- -018 C3 6.58669900e-021

C4 -5. , 14236275e- -020 C4 2,, 25402896e- -024 C4 -2.03332737e-023

C5 -4. , 70980651e- -024 C5 3., 72242911e- -028 C5 -2.20168557e-029

C6 2. .65671689e- -027 C6 3, .20803731e- -031 C6 -6.84618723e-032

C7 -2. , 41428161e- -031 C7 4.14434278e-036

AREA NO. 10 AREA NO. 43

K 0.0000 K 0.0000

Cl 1.08458836e-008 Cl -1.52986987e-009

C2 6.34606387e-013 C2 -1.10887104e-014

C3 -4.79999941e-017 C3 -1.19044876e-018

C4 -3.88550006e-021 C4 -2.65113635e-023

C5 -7.97813456e-026 C5 1.01435593e-027

C6 5.17810873e-029 C6 1.25351252e-031

C7 -3.15751405e-033 C7 -9.10473118e-036

AREA NO. 23

K 0.0000

Cl 1.86228378e-007

C2 1.34530827e-011

C3 1.90817638e-015

C4 2.47700195e-020

C5 1.48998352e-022

C6 -3.26357684e-026

C7 6.39194153e-030 TABLE 5 (ml 659a)

FRESH NUMBER 1/2 FREE

AREA RADIANS I THICK GLASSES 193.304nm DIAMETER

0 0. 000000000 32. 000000000 L710 0. 99998200 56. 080

1 0. 000000000 3. 100000000 L710 0. 99998200 63.460

2 0. 000000000 8. 000000000 SI02HL 1. 56028900 64. 175

3 214.374691678 6. 768422494 HE193 0. 99971200 66.898

4 678. 966348965AS 8. 000000000 SI02HL 1. 56028900 68. 402

5 295. 639011035 37. 169733715 HE193 0. 99971200 69. 900

6-111. 652887331 16. 192909187 SI02HL 1. 56028900 71.248

7 1435.846896630AS 2. 614024194 HE193 0. 99971200 97,000

8 1427.381076990 41.812512207 SI02HL 1.56028900 100.696

9 -207. 640254189 0. 700000000 HE193 0. 99971200 106.045

10 584,088602595AS 42,576490437 SI02HL 1,56028900 132,378

11-481. 678249044 0. 700000000 HE193 0. 99971200 134. 179

12 406. 807321876 35. 706452882 SI02HL 1. 56028900 142. 827

13-5625. 700893160 0. 700000000 HE193 0. 99971200 142.670

14 298. 176737082 79. 446714434 SI02HL 1. 56028900 140. 967

15 -13921. 627398000 3., 719595268 HE193 0. 99971200 131.651

16 448. 349842071 28. 279136919 SI02HL 1. 56028900 123. 944

17 1417. 631668090 0., 792030769 HE193 0. 99971200 118.744

18 223.937979671 14. 944850216 SI02HL 1. 56028900 107.384

19 146th, 318064199 3rd, 170742365 HE193 0th 99971200 95,625

20 122nd, 769528398 41st .476354079 SI02HL 1st, 56028900 92nd, 370th

21 392., 244315955 7., 795170437 HE193 0. 99971200 86. 941

22 704. .124769671 12. .864149054 SI02HL 1. .56028900 84., 284

23 206. .226483591AS 41., 697630229 HE193 0., 99971200 71. 571

24-136. .542261472 8. .000000000 SI02HL 1. .56028900 68., 125

25 188.276100920 34., 851670699 HE193 0. .99971200 66., 714

26-266. .296401208 11. .337537040 SI02HL 1. .56028900 68., 908

27 828.502027259 27..472554480 HE193 0., 99971200 73., 632

28-188. .039957784 10. .048803630 SI02HL 1. .56028900 76., 651

29-286. .338776941 11. .364281707 HE193 0. .99971200 82., 442

30-195. .263210167 27. .977992639 SI02HL 1. .56028900 84. .451

31 -210. .425554231AS 2. .668847644 HE193 0. .99971200 95., 869

32 -359, .454820504 33, .263873624 SI02HL 1. .56028900 100., 866

33 -179, .268898245 19, .520108899 HE193 0. .99971200 105., 926

34 301 .090725759 12 .000000000 SI02HL 1. .56028900 123. .535

35 210, .449149431 31, .394452961 HE193 0. .99971200 122. .750

36 708 .827802225AS 12 .000000000 SI02HL 1. .56028900 124. .201

37 368.. 041113973 9, .972701330 HE193 0. .99971200 128. .960

38 399 .107567619 4 .538775677 SI02HL 1, .56028900 136. .284

39 -764 .045549260 0, .700000000 HE193 0, .99971200 137. .910

40 551 .145029040 48 .906287759 SI02HL 1, .56028900 145, .979

41 -510 .329983328AS 33 .432166582 HE193 0, .99971200 146, .810

42 -234 .804925584 15 .000000000 SI02HL ^' 1. .56028900 146, .808

43 -435 .743783861 24. .039044390 HE193 0, .99971200 156, .860

44 0 .000000000 1. .800000000 HE193 0, .99971200 158, .282

45 548 .700219435AS 15 .000000000 SI02HL 1. .56028900 173, .490

46 301 .445277190 13 .491008474 HE193 0, .99971200 174. .191

47 366 .662373729 87 .073931844 SI02HL 1. .56028900 176, .150

48 -550 .992057843AS 0. .700000000 HE193 0. .99971200 177, .412

49 470 .272792479 71. .690763514 SI02HL 1. .56028900 176, .239

50 -524 .235839398AS 0 .700000000 HE193 0. .99971200 175 .005

51 143 .906521816 40 .003798335 SI02HL 1 .56028900 123 .753

52 189 .600309947 1 .071971036 HE193 0 .99971200 116 .154

53 144 .836316227 31 .828068261 SI02HL 1 .56028900 108 .008

54 218 .443210665 0 .700000000 HE193 0 .99971200 100 .536

55 190 .712173887 25 .768276703 SI02HL 1 .56028900 9 .024

56 370 .701088466 9 .564358749 HE193 0 .99971200 87 .535

57 807 .447019199 15 .749130690 SI02HL 1 .56028900 80 .461

58 171 .924005396 7 .148775604 HEI93 0 .99971200 61 .353

59 181 .279659482 24 .378394256 CAF2HL 1 .50143600 55 .679

60 1752 .925125720 3 .615508978 L710 0 .99998200 42 .509

61 0 .000000000 3 .000000000 SI02HL 1 .56028900 34 .651

62 0 .000000000 8 .000000000 L710 0 .99998200 32 .423

63 0 .000000000 14 .020 TABLE 6

AREA NO. 4 AREA NO. 31 'LAEC1 HE NO. 48

K 0.0000 K 0.0000 K 0.0000 Cl 1.89471885e- -007 Cl 7.59066257e-009 Cl -2.57047835e- -011 C2 -6.02710229e - 012 C2 -5.13712565e-013 C2 2.34238635e- -014 C3 1.53417903e - 016 C3 -1.12360493e-017 C3 2.59035963e- -019 C4 -2.42817642e - 020 C4 -1.78576425e-021 C4 2.27193081e- -024

C5 9.58992339e-026 C5 5.82554954e- -029

C5 5.70562716e- -024 C6 -6.73381570e-030 C6 4.60561363e- -033 C6 -7.46671442e - 028 C7 -4.21140368e- -038 C7 4.25930704e - 032

AREA NO. 7 AREA NO. 36 AREA NO. 50

K 0.0000 K 0.0000 K 0.0000

Cl 3.66131696e-009 Cl 1.25923077e-009 Cl 4.01128359e-010

C2 -1.30949841e-013 C2 -2.53075485e-014 C2 2.65597086e-015

C3 1.06295513e-016 C3 3.04931813e-018 C3 6.44693849e-020

C4 -9.94272982e-021 C4 -1.11476591e-022 C4 4.81837039e-024

C5 3.83041775e-025 C5 -2.12954081e-027 C5 1.01089127e-028

C6 2.71682194e-030 C6 3.80719952e-031 C6 -5.98482220e-033

C7 -5.66222517e-034 C7 -1.32616533e-035 C7 1.07932955e-037

AREA NO. 10 AREA NO. 41

K 0 0.0000 K 0.0000

Cl --55.39079178e-010 Cl 8.47964979e-010

C2 1 65472968e-013 C2 1.31624211e-014

C3 -1 48200988e-018 C3 -6.67941632e-019

C4 -4 26542196e-022 C4 -2.85032922e-023

C5 2 23375010e-026 C5 9.45648624e-028

C6 -4 68780777e-031 C6 3.12077825e-033

C7 2 49086051e-036

AREA NO. 23 AREA NO. 45

K 0. .0000 K 0.0000

Cl 1. .12693938e- -007 Cl -3.98398365e-009

C2 3rd, 12498460e- -012 C2 -8.63014001e-015

C3 1. .69981511e- -016 C3 1.08554002e-018

C4 3. .48067953e- -020 C4 3.83549756e-025

C5 -5. .03222312e- -024 C5 4.90933881e-028

C6 8, .68868128e- -028 C6 5.51369375e-033

C7 -3. , 88286424e- -032 C7 -2.09514835e-037

TABLE 7 (Shs2010)

FRESH NUMBER 1/2 FREE

AREA 1 ΪIADIA 1 THICK GLASSES 157.629nm DIAMETER

0 0. 000000000 27. 200000000 N2V157 1. 00031429 45. 607

1 0. 000000000 1. 078880752 N2V157 1. 00031429 52. 255

2 1045. 314373860AS 7th, 513476207 CAF2V157 1. 55929035 53. 175

3 114. 248430605 5. 626540893 N2V157 1. 00031429 54. 906

4 186.055500442AS 9, 260588934 CAF2V157 1. 55929035 57.362

5 182,39399171 22,5566534529 N2V157 1,000,31429 58,070

6-183. 513133835 7th, 502341067 CAF2V157 1st 55929035 59,394

7 283.035779024AS 6th, 154441203 N2V157 1,00031429 69,752

8 401. .580615857 36., 640413384 CAF2V157 1. 55929035 74. 376

9-281. 777697307 0., 861477292 N2V157 1.00031429 82. 029

10 353. .134032777AS 21., 777939897 CAF2V157 1. 55929035 96. .624

11 6025. 441766310 0., 939333289 N2V157 1. 00031429 97. 803

12 215. 727113313 16., 642509432 CAF2V157 1. 55929035 104. 912

13 311., 039356614 1., 720069535 N2V157 1. 00031429 104. 543

14 228. 409410676 53. 091993802 CAF2V157 1. 55929035 105. 751

15-758. , 217583901 0., 700000000 N2V157 1. 00031429 103. 603

16 132. 798453265 34. 216733306 CAF2V157 1. 55929035 92. 164

17 325., 068121782 0. .700376490 N2V157 1., 00031429 87. 829

18 274.542764700 14., 522646582 CAF2V157 1. 55929035 86.310

19 338., 880545591 0., 701615532 N2V157 1., 00031429 81., 119

20 290. 554636535 35., 428116482 CAF2V157 1. 55929035 79. 777

21 3517., 019128770 8., 536647573 N2V157 1., 00031429 66., 983

22 -432. 647390565 7th, 503695666 CAF2V157 1st 55929035 63,895

23 351., 066950680AS 27., 713652572 N2V157 1., 00031429 55., 675

24-96. 698497704 6th, 786155040 CAF2V157 1st, 55929035 54th, 460

25 409, 131134381 22nd, 127454363 N2V157 1st, 00031429 55th, 555

26 -112. , 905403831 7th, 514387520 CAF2V157 1st, 55929035 56th, 043th

27 648., 671802143 18, .457185848 N2V157 1., 00031429 63., 374

28-184. , 515622336 13th, 993219919 CAF2V157 1st, 55929035 65th, 303

29 1230., 992852820 11. .356478659 N2V157 1., 00031429 79., 407

30 -2362. , 593927680 29. .065160418 CAF2V157 1., 55929035 87., 263

31 -316. .217892752AS 1. .235135355 N2V157 1. .00031429 96., 738

32 -382. , 379645390 44 .746901069 CAF2V157 1. .55929035 98., 349

33 -129. .769453881 0. .793115744 N2V157 1. .00031429 102., 434

34 340.264743344 12. .064670296 CAF2V157 1., 55929035 119., 942

35 229 .694535355 31 .128991673 N2V157 1 .00031429 120. .145

36 1287. .330025580AS 9. .736539177 CAF2V157 1. .55929035 121. .539

37 364. .756756968 9, .358478921 N2V157 1. .00031429 127. .928

38 397 .094346162 41. .827853290 CAF2V157 1. .55929035 136. .576

39-976. .995908198 0. .786915821 N2V157 1. .00031429 138. .444

40 410.514102518 80.508348674 CAF2V157 1. .55929035 150. .286

41 -324. .940917692AS 28. .497218849 N2V157 1. .00031429 150. .806

42 -210. .576089850 12. .724040700 CAF2V157 1. .55929035 149. .372

43 -405, .186570491AS 54. .127665200 N2V157 1. .00031429 157, .522

44 0, .000000000 -32, .315024000 N2V157 1, .00031429 161, .249

45 367, .399928082AS 12, .724040700 CAF2V157 1, .55929035 163, .212

46 234, .556148176 15, .776145720 N2V157 1. .00031429 158, .116

47 262, .828171603 81, .195503690 CAF2V157 1, .55929035 162, .673

48 -725, .847919437AS 0 .700158254 N2V157 1 .00031429 162 .170

49 246, .701752532 66. .006758182 CAF2V157 1, .55929035 152 .284

50 -2127 .666595970AS 0 .700000000 N2V157 1 .00031429 148 .983

51 139, .223624657 30 .839009177 CAF2V157 1 .55929035 110 .611

52 186 .041725727 0 .700000000 N2V157 1 .00031429 103 .950

53 144 .468793673 48 .246174525 CAF2V157 1 .55929035 97 .488

54 576 .304531006AS 11 .297930555 N2V157 1 .00031429 82 .155

55 -1203 .254778000 12 .806934866 CAF2V157 1 .55929035 73 .193

56 670 .188680719 2 .550471395 N2V157 1 .00031429 60 .877

57 358 .370758649 16 .126420420 CAF2V157 1 .55929035 55 .058

58 -2011 .367216580 2 .181264120 N2V157 1 .00031429 46 .664

59 0 .000000000 7 .500000000 CAF2V157 1 .55929035 38 .403

60 0 .000000000 7 .000000000 N2V157 1 .00031429 32 .640

61 0 .000000000 11 .402 TABLE 8

AREA NO. AREA NO. 31 AREA NO.

K 0. .0000 K 0., 0000 K 0.0000

Cl 1., 43214516e- -007 Cl 3., 37616068e- -008 Cl -1.11964446e-009

C2 -1. .05523323e- -011 C2 -1, .35772165e- -012 C2 1.27445676e-013

C3 1., 33937296e- -014 C3 -9. , 13855026e- -017 C3 -6.74866729e-020

C4 -3. , 81541827e- -018 C4 2., 55494973e- -021 C4 3.35598915e-023

C5 7. .71238693e- -022 C5 8. .18743728e- -026 C5 1.67085809e-027

C6 -1. , 24242959e- -025 C6 -3. .21333945e- -030 C6 -9.92306326e-033

C7 1. .04382716e- -029 C7 -1, .70882417e- -034 C7 4.04149705e-037

AREA NO. AREA NO. 36 AREA NO. 50

K 0.0000 K 0. .0000 K 0. .0000

Cl 4.22469071e-007 Cl 3., 39133645e- -009 Cl 1. .68697911e- -009

C2 -2.02044975e-011 C2 -1. , 01165561e- -013 C2 6., 71519010e- -014

C3 -9.99096667e-015 C3 -4, .16392158e- -018 C3 -1, .12711844e- -018

C4 2.57319928e-018 C4 -4. .60775252e- -023 C4 -3. .58730491e- -023

C5 -3.55404240e-022 C5 -4, .18366165e- -027 C5 4, .82205527e- -028

C6 2.76031008e-026 C6 -3. .56809896e- -032 C6 2, .73665299e- -032

C7 -1.04425360e-030 C7 6, .85585311e- -036 C7 -6, .49697083e- -037

AREA NO. AREA NO. 41 AREA NO. 54

K 0. .0000 K 0. .0000 K 0. .0000

Cl 6 .69007068e- -008 Cl -1. .50447859e- -009 Cl 8, 11862732e- -010

C2 -8. .14794171e- -012 C2 -4. , 05442091e- -014 C2 9. .24410971e- -014

C3 1. .44046983e- -016 C3 -1. .06684952e- -019 C3 4 .20674572e- -018

C4 -6. .18733673e- -020 C4 -2. .92843853e- -023 C4 1. .09384658e- -021

C5 1. .33863248e- -024 C5 4, .58323842e- -028 C5 -1 .19932277e- -025

C6 6. .01771051e- -028 C6 2. .24810472e- -032 C6 5 .78613553e- -030

C7 -4. .18169671e- -032 C7 3 .26320529e- -037 C7 -3 .28204739e- -034

AREA NO. 10 AREA NO. 43

K 0.0000 K 0. .0000

Cl 2.09103125e-008 Cl -1. , 43187993e- -009

C2 3.74013441e-013 C2 8. .61397718e- -015

C3 -4.28287142e-017

C4 -7.74198571e-021 C3 -4, .27133053e- -019

C5 7.15651505e-025 C4 -1. .67623847e- -023

C6 -2.00926873e-029 C5 7., 56870039e- -028

C7 -1.13570242e-034 C6 4., 59600825e- -032

C7 -1. , 56107786e- -036

AREA NO. 23 AREA NO. 45

K 0 0.0000 K 0.0000

Cl 2 79935405e-007 Cl -7.40459945e-009

C2 1 51575623e-011 C2 -9.68327166e-015

C3 1 48076409e-015 C3 4.20547857e-018

C4 1 1.82749522e-019 C4 -2.29946961e-023

C5 4 42569184e-023 C5 1.66748551e-027

C6 -6 6.88248081e-027 C6 4.76274324e-032

C7 2 98012936e-030 C7 -1.41676650e-036 TABLE 9 (SHS2007)

FRESH NUMBER 1/2 FREE

AREA] RADIANS I THICK GLASSES 193.304nm DIAMETER

0 0. 000000000 33. 600000000 L710 0. 99998200 54.406

1 0. 000000000 0. 700000000 L710 0. 99998200 62.622

2 6082.059008953AS 8. 000000000 SI02HL 1.56028895 63.203

3 143.971066538 5. 220564877 HE193 0. 99971200 65.679

4 220. 728491318AS 14. 894807261 SI02HL 1. 56028895 67. 999

5 255. 425625405 25. 437504335 HE193 0. 99971200 69. 274

6 -213. 790257832 8. 000767193 SI02HL 1. 56028895 70.7782

7 363.835685805AS 7. 715328993 HE193 0. 99971200 82.296

8 609, 577684342, 43, 913943130 SI02HL, 56028895, 86, 335

9 -315. 746821165 0. 872144807 HE193 0. 99971200 96.478

10 455. 762005384AS 27. 106087992 SI02HL 1. 56028895 113. 107

11 7229. 021339243 0. 704758668 HE193 0. 99971200 115.284

12 251. 626671247 20. 976022785 SI02HL 1. 56028895 124. 960

13 363.067076891 3.470948804 HE193 0.99971200 124.571

14 282, 856636492 67, 559653556 SI02HL 1,56028895 126, 222

15 -901. 244370913 2. 358079827 HEI93 0. 99971200 123.665

16 160., 340001669 41. .155799240 SI02HL 1. 56028895 111. 328

17 490. 332334286 1. 787006860 HE193 0. 99971200 107.624

18 400., 692503878 17., 482624917 SI02HL 1. 56028895 105., 263

19 1050., 089846531 1., 273289975 HE193 0. 99971200 101. 323

20 682., 408004442 43., 747762196 SI02HL 1. 56028895 98., 609

21 3103., 102640660 10., 767552226 HE193 0. 99971200 79., 838

22 -449. , 343998255 8th, 151994354 SI02HL 1,56028895 76th, 964

23 481. .606355829AS 34. .236197830 HEI 93 0., 99971200 67., 953

24-121. .665966102 8. .400000000 SI02HL 1. 56028895 65., 854

25 374. 980814433 26 .204024332 HE193 0., 99971200 67., 217

26-143. .249767685 8. .035536657 SI02HL 1., 56028895 67., 743

27 884. .703729247 23. .779221943 HE193 0., 99971200 76., 105

28 -243. .498696219 18. .114116074 SI02HL 1., 56028895 80. .078

29 11014. .244296721 14..108602625 HEI 93 0., 99971200 95., 668

30 -1710. .670778965 36. .476108265 SI02HL 1. .56028895 105. .564

31-509. .290793668AS 3. .799046038 HE193 0., 99971200 120. .040

32 -522. .760271037 55. .102056532 SI02HL 1., 56028895 121., 425

33 -162, .101214724 0, .700000000 HE193 0. .99971200 126. .271

34 408.832035177 12. .000000000 SI02HL 1. .56028895 148. .654

35 285, .314514094 38. .599460894 HE193 0. .99971200 148. .869

36 1647, .197381837AS 12. .000000000 SI02HL 1. .56028895 150. .501

37 452, .111295331 11. .431144357 HE193 0. .99971200 158. .593

38 495 .143365449 50, .265656014 SI02HL 1, .56028895 169, .187

39-1181. .451218240 0, .700000000 HE193 0. .99971200 171. .160

40 504 .444538837 108 .309739630 SI02HL 1, .56028895 186 .338

41 -402 .406909600AS 35 .218931962 HEI 93 0. .99971200 187, .299

42 -260 .687700983 15 .750000000 SI02HL 1, .56028895 185, .680

43 -501 .804439493AS 67 .000000000 HE193 0. .99971200 196 .016

44 0 .000000000 -40 .000000000 HE193 0. .99971200 200 .793

45 439 .023921910AS 15 .750000000 SI02HL 1 .56028895 203 .535

46 286 .281672961 18 .419961595 HE193 0. .99971200 196 .728

47 320 .640783540 98 .196888764 SI02HL 1. .56028895 201 .435

48 -938 .097514827AS 0 .700000000 HE193 0 .99971200 200 .897

49 302 .624264758 84 .618876500 SI02HL 1 .56028895 188 .254

50 -3200 .587702255AS 0 .730670643 HE193 0 .99971200 182 .786

51 170 .842340056 38 .317749380 SI02HL 1 .56028895 136 .139

52 222 .792535873 1 .144357720 HEI93 0 .99971200 127 .200

53 170 .961511698 59 .825366410 SI02HL 1 .56028895 118 .623

54 671 .886005497AS 14 .144748840 HE193 0 .99971200 100 .059

55 -1782 .275044587 16 .050043219 SI02HL 1 .56028895 86 .783

56 683 .979935539 3 .683343415 HE193 0 .99971200 71 .293

57 415 .132395267 20 .066273975 SI02HL 1 .56028895 64 .045

58 -3089 .397426921 2 .700000000 L710 0 .99998200 53 .104

59 0 .000000000 3 .150000000 SI02HL 1 .56028895 43 .475

60 0 .000000000 9 .000000000 L710 0 .99998200 41 .056

61 0 .000000000 13 .602 Table 10

AREA NO. 2 C5 2. 76794296e- -027 K 0. 0000 C6 -3. 72884626e- -031 Cl 9. 18566931e- -010

K 0.0000 C7 5. 44983867e- -037 C2 2. 34181695e- -014

Cl 6.13378195e-008 C3 -2. 37718980e- -019

C2 -1.21093962e-012 C4 -4. 99822008e- -024

C3 4.03974995e-015 iE NO. 36 C5 4. 49770758e- -029

C4 -9.55444255e-019 C6 1. 89095883e- -033

C5 1.47785598e-022 K 0. 0000 C7 -3. 25678700e- -038

C6 -1.63598785e-026 Cl 1. 62423735e- -009

C7 8.81916303e-031 C2 -2. 90322074e- -014

C3 -1. 28032707e- -018 AREA NO. 54

C4 -8.13073474e-024

AREA NO. 4 C5 -2.82547328e-028 K 0.0000

C6 -1.12054203e-032 Cl 4.98993424e-010

K 0.0000 C7 3.63330556e-037 C2 2.96497812e-014

Cl 2.40106346e-007 C3 7.13814561e-019

C2 -1.01253531e-011 C4 6.37411566e-023

C3 -3.29559355e-015 AREA NO. 41 C5 -9.87253699e-027

C4 7.33617239e-019 C6 8.78681835e-031

C5 -8.72083684e-023 K 0.0000 C7 -3.08278753e-035

C6 6.00312066e-027 Cl -8.25877332e-010

C7 -1.80286882e-031 C2 -1.35293772e-014

C3 -1.52207044e-019

C4 -3.79513424e-024

AREA NO. 7 C5 4.70194280e-029

C6 1.38778762e-033

K 0.0000 C7 2.29251252e-038

Cl 4.18009370e-008

C2 -2.90287476e-012

C3 -6.63126937e-017 AREA NO. 43

C4 -1.02006062e-020

C5 1.19401776e-024 K 0.0000

C6 -3.86272749e-029 Cl -7.55685880e-010

C7 1.07942556e-033 C2 3.51491917e-015

C3 -1.00447098e-019

C4 -2.72274784e-024

AREA NO. 10 C5 7.10036568e-029

C6 2.88999682e-033

K 0.0000 C7 -6.70709105e-038

Cl 1.02570958e-008

C2 1.91710967e-013

C3 -2.01472753e-017 AREA NO. 45

C4 -9.85838048e-022

C5 8.93935503e-026 K 0.0000

C6 -2.25592871e-030 Cl -3.91274835e-009

C7 6.58672348e-036 C2 -3.25534545e-015

C3 9.56631278e-019

C4 -3.12533946e-024

AREA NO. 23 C5 1.64402231e-028

C6 3.02878298e-033

K 0.0000 C7 -6.01532104e-038

Cl 1.54526224e-007

C2 5.83194952e-012

C3 3.45258425e-016 AREA NO. 48

C4 3.91617672e-020

C5 4.12332466e-025 K 0.0000

C6 3.60449958e-028 Cl -5.54279925e-010

C7 5.30220523e-032 C2 4.37404892e-014

C3 -2.36005962e-020

C4 5.02991088e-024

AREA NO. 31 C5 1.62614899e-028

C6 -6.64121367e-034

K 0.0000 C7 1.69853177e-038

Cl 1.96722680e-008

C2 -5.31456030e-013

C3 -2.13215304e-017 AREA NO. 50

C4 7.69697830e-022

Claims

claims

1. projection lens for imaging a pattern arranged in the object plane of the projection lens into an image plane of the projection lens with ultraviolet light of a predetermined working wavelength, the projection lens with: a plurality of optical elements which are arranged along an optical axis; and a system diaphragm (5) arranged at a distance from the image plane; wherein the projection lens is designed as a purely refractive one-waist system with an abdomen (6) close to the object, an abdomen (8) close to the image and an intermediate waist (7) and in one

A negative group (LG5) is arranged in the area of divergent radiation between the waist (7) and the system diaphragm (5) and has an effective curvature with a concave side directed towards the image.

2. Projection objective according to claim 1, wherein the negative group (LG5) comprises at least one lens (27, 28) with negative refractive power and a concave surface directed towards the image.

3. Projection objective according to claim 1 or 2, in which the negative group (LG5) comprises at least two, in particular exactly two, lenses (27, 28) with negative refractive power and concave surfaces directed towards the image, preferably the refractive power of the object-side lens (27) thereof Group is greater than the refractive power of a subsequent lens (28) of the group.

4. Projection lens according to one of the preceding claims, in which the negative group (LG5) is arranged in a central region between a location of the narrowest constriction of the waist (7) and the system diaphragm (5), preferably an apex of a curvature surface of the negative group in the range between approx 30% and approx. 70%, in particular between approx. 40% and approx. 60% of the axial distance between the area of the narrowest constriction of the waist (7) and the system cover (5).

5. Projection lens according to one of the preceding claims, in which the negative group (LG5) has an effective curvature with a curvature radius r _c , whose ratio r _c / DB to the diaphragm diameter DB of the system diaphragm (5) in the range between approximately 0.8 and approximately 2.2 is preferably in the range between approximately 1.0 and approximately 2.0, in particular in the range between approximately 1.1 and approximately 1.9.

6. Projection objective according to one of the preceding claims, in which in the area of the system diaphragm (5) an essentially symmetrical construction with biconvex lenses (29, 30, 33, 34) and

Negative meniscus lenses (31, 32) are present.

7. Projection objective according to one of the preceding claims, in which a negative meniscus lens (31) with an object-side concave surface and immediately behind the system aperture a negative meniscus lens (32) with an image-side concave surface is arranged directly in front of the system aperture (5).

8. Projection lens according to one of the preceding claims, in which immediately before the system aperture (5) a positive / negative

Doublet with a biconvex lens (30) and a subsequent negative meniscus lens (39) with a concave surface on the object side and A negative / positive doublet with a negative meniscus lens (32) with a concave surface on the image side and a subsequent biconvex lens (33) is arranged indirectly behind the system diaphragm.

9. Projection objective according to one of the preceding claims, in which at least one biconvex positive lens, preferably two biconvex positive lenses (33, 34), is arranged between the system diaphragm (5) and the image plane (3).

10. Projection objective according to one of the preceding claims, in which the last optical surface before the system diaphragm (5) and / or the first optical surface after the system diaphragm is aspherical.

11. Projection lens according to one of the preceding claims, which is designed for a working wavelength of 248nm, 193nm or 157 nm.

12. Projection lens according to one of the preceding claims, in which all transparent optical elements, possibly with the exception of at least one image-near lens, are small

Diameter and an end plate, are made of the same material, especially synthetic quartz glass.

13. Projection lens according to one of the preceding claims, which has an image-side numerical aperture NA> 0.85, preferably NA> 0.9.

14. Projection objective according to one of the preceding claims, in which at least one positive meniscus lens (26) with a concave surface on the object is arranged between the waist (7) and the system diaphragm (5) in the vicinity of the waist.

15. Projection objective according to one of the preceding claims, in which at least one lens (26) with an image-side convex surface and subsequently at least one lens (27, 28) with an object-side convex surface are arranged between the waist (7) and the system diaphragm (5) in this order is, wherein preferably the first lens with a convex surface on the image side has a positive refractive power.

16. Projection objective according to one of the preceding claims, wherein a negative group with at least two negative lenses (2, 3, 4) is arranged in the region of the waist (7), the negative group preferably having at least three successive negative lenses.

17. Projection objective according to one of the preceding claims, in which one of the first lens groups following the object plane has at least two negative lenses (11, 12).

18. Projection objective according to claim 17, in which in the first lens group at least one of the first four optical surfaces following the object plane is aspherical, preferably in the first lens group at least two optical surfaces are aspherical, and in particular lie on the object side.

19. Projection objective according to one of the preceding claims, in which at least one meniscus lens (16, 18) with a positive refractive power and a concave surface on the image side is arranged in the region of large beam diameters in the vicinity of the object plane (2).

20. Projection objective according to one of the preceding claims, in which at least one aspherical surface in the region of the waist (7) and at least one aspherical surface is arranged in the area of the system diaphragm (5).

21. Projection objective according to one of the preceding claims, in which for the parameters:

A = maximum angle of incidence (in gas) of the image side

Exit surface of a lens of the negative group (LG5) in the ascending area of the second abdomen (8); B = maximum angle of incidence (in gas) of the image side

Exit surface of the last lens (24) with a negative refractive power in the

Waist (7).

C = ratio between edge jet height at A and maximum

Coma jet height at A D = ratio between edge jet height at B and maximum

Coma beam height at B the condition: A / B> C / D applies

22. Projection lens according to one of the preceding claims, in which a large negative lens (32) after the system aperture (5) has an effective curvature that has the same orientation as an effective curvature of the negative group (LG5) in the ascending

Area between waist (7) and system panel (5).

23. Projection objective according to one of the preceding claims, in which the effective curvature changes between the waist (7) and system diaphragm (5) at least between two lenses (26, 27), so that a change in the position of the centers of curvature of the effective curvature takes place.

24. Projection objective according to one of the preceding claims, in which an adjustable spherical diaphragm is provided in the area of the system diaphragm.

25. Projection lens according to one of the preceding claims, in which in an area of large beam diameter in the vicinity of the object plane (2) at least between two lenses (14, 15) with positive refractive power the effective curvature changes from the object side to the image side, so that a change in position the center of curvature of the effective curvature takes place.

26. Projection objective according to one of the preceding claims, in which in an area of large beam diameter near the image plane (3) behind the system diaphragm (5) there are at least two aspherical lenses (33, 34) with image-side aspherical surfaces, the diameter of which is at least 75% of the Improvement of the system cover is.

27. Projection lens according to one of the preceding claims, in which in a region between the system aperture (5) and the image plane

(3) at least three lenses (33, 34, 36) with a positive refractive power are aspherized on the image side and there is no further aspherized lens with an object-side aspherical surface between these lenses.