DE10229816A1 - Apparatus for generating a convergent light wave front for intereferometric measurement of convex lens surfaces using an arrangement of mirrors - Google Patents

Abstract

The apparatus for generating a convergent optical wave front (4) has first and second aspherical mirrors (2,3) arranged one after the other in the beam path and out of axis. The second mirror is a concave ellipsoidal mirror. The first mirror is also a concave ellipsoidal mirror geometrically similar to the second mirror. The two mirrors are arranged such that the exit focal point of the first mirror is coincident with the entry focal point of the second mirror. Independent claims also cover a system for interferometric lens surface measurement.

Description

The invention relates to a Device for generating a convergent light wavefront with a first and a second aspherical mirror in the light beam path successive off-axis are arranged, the second mirror a concave, at least nearly ellipsoidal Mirror, as well as on a system for interferometric measurement of convex lens surfaces. Under the expression "at least nearly ellipsoidal "are said to be like familiar to the expert, on the one hand, mirror with a perfectly elliptical or ellipsoidal shape be understood, on the other hand also those that are for the purpose of optimization their mapping properties are slightly different from the mathematically exact Ellipsoid surface shape deviating Mirror surface design exhibit.

It is known to have convex surfaces optical lenses during of the manufacturing process as a standard to be measured interferometrically and so to check for compliance with certain target specifications for the lens surface. Such test optics are used, for example, for surface inspection of Lenses for Lenses applied in projection exposure systems at the Semiconductor manufacturing can be used.

usual test optics for this Applications include so-called aplanar optics or Fizeau aplanar optics, which consist of up to six lenses and a convergent spherical light wavefront produce. These optics are also designed to be a field of a certain size, e.g. for up at 0.5 ° angle of incidence of a parallel beam to the optical axis of the lens, for which the aberrations of one passing through the aplanar optics Wavefront below a reasonable limit, e.g. some wavelength of the laser light used. This field behavior of the test optics is reduced the negative impact of drifts on the result of interferometric Lens surface inspection. newer Generations of lenses for semiconductor manufacturing has increasingly larger diameters. consequently have to with the conventional test optics Lenses are used that have a correspondingly high aperture ratio or a correspondingly low number of openings exhibit. Their production is relatively complex.

In the published application DE 199 36 936 A1 describes a device for focusing light onto an output focus and consequently for producing a convergent light wavefront, which comprises a first, convex aspherical mirror, preferably a hyperboloid mirror, and a second, concave aspherical mirror, preferably an ellipsoidal or paraboloid mirror, which in the Light beam path are successively arranged off-axis. A light source is arranged at the entrance focus of the first mirror. The two mirrors are arranged so that the entrance focus of the concave mirror coincides with the virtual exit focus of the convex mirror.

To correct spherical Aberration and coma is called F / 4-Aplanatic-Gregorian an axial arrangement of two ellipsoid mirrors facing one another, concave mirror surfaces known in different sizes. A parallel beam of light is reflected by the larger one reflects the smaller mirror and from it to an output focus focused, with the smaller mirror shading the larger and the larger mirror an axial passage opening has in the shading area.

The invention lies as a technical Problem of providing a device for generating a convergent light wavefront and a system for interferometric Measurement of convex lens surfaces of the type mentioned at the beginning underlying, where a convergent with relatively little effort Light wavefront with a high aperture ratio disposal stands, which is particularly for interferometric measurement of convex lens surfaces huge Diameter is suitable.

The invention solves this problem by providing it a device for generating a convergent light wavefront with the features of claim 1 and a system for interterometric Measurement of convex lens surfaces with the characteristics of the Claim 5.

The device according to the invention uses two concave, at least approximately ellipsoidal Off-axis mirror Arrangement positioned so that the exit focal point of the first mirror in the light beam path with the entry focal point of the second mirror following in the light beam path coincides. Essential with regard to the field behavior of the mirror arrangement, it is the further that both mirrors are geometrically similar in shape, including It should be understood in the present case that they are sections of geometrically similar Represent ellipsoids, i.e. of ellipsoids of equal eccentricity, whose Semi-axes differ by an equally large factor. The Field behavior of the entire imaging system can also change the shape slightly the mirror, i.e. due to slight deviations from a perfect one elliptical shape.

It can be seen that the desired field behavior is achieved with this mirror arrangement. Looking at the image of a single ellipsoid mirror, coma is the dominant wavefront aberration in the field. In the arrangement according to the invention, this field coma is compensated for by the second ellipsoid mirror. In addition, this arrangement can be implemented with comparatively little effort and enables the provision of a convergent light wavefront with a high aperture ratio, ie low number of openings.

A further developed according to claim 2 Device points in the light beam path after the second ellipsoid mirror a meniscus lens in front of its exit focal point. With this can the focal length of the outlet and thus the space required for the overall structure be kept low. At the same time, the exit surface of the Meniscus lens as a reference surface e.g. For interferometric test measurements serve. In the case of an interpretation of the two mirrors on one perfectly The meniscus lens is elliptical in shape and concentric designed so that its convex side is an aplanatic illustration causes and the light rays of those passing through the lens The wavefront should be perpendicular to the surface of the concave lens surface. With minor one of the mirrors deviating from the exact ellipsoid shape can do this suitable variation of the radius of the convex side of the meniscus lens is provided his.

A further developed according to claim 3 Device includes an entry-side focusing lens arrangement, which the incoming light onto the entry focus of the first concave mirror focused from where it is in through the two mirrors Direction of focus of the second mirror is guided.

In an advantageous embodiment is the device on an opening number of about 0.8 or less. It can be used to converge Provide light wave fronts that are also interterometric Measurement of convex lens surfaces of large diameter are suitable as they are in modern projection exposure systems in semiconductor technology be used.

The system according to the invention for interferometric Measurement of convex lens surfaces is possible with the device according to the invention for generating a convergent light wavefront including a meniscus lens equipped, taking the concave side of the meniscus lens as the reference surface for the interterometric Measurement of a respective convex lens surface is used. Through this system you can also relatively large diameter lenses measured interferometrically with comparatively little effort become.

Advantageous embodiments of the invention are shown in the drawings and are described below. Here show:

1 a schematic representation of a test lens for interferometric measurement of convex lens surfaces with an opening number of 0.8 and

2 a schematic representation of a test lens accordingly 1 , but dimensioned to an opening number of 0.57.

1 shows a device for generating a convergent light wave front in use as inspection optics for interferometric measurement of convex lens surfaces, in particular the surfaces of lenses, such as those used in lenses of projection exposure systems for photolithographic processes in semiconductor technology. The inspection optics include a focusing lens arrangement on the light entry side 1 with a small input beam diameter with an opening number of approximately 1.15 to 1.2, which direct the incoming light beam onto an entry focus F _{E1 of} a subsequent first concave ellipsoid mirror 2 focused, which is arranged off-axis. As a result, the light from this ellipsoid mirror 2 focused on its exit focus F _A1 .

The first ellipsoid mirror 2 a larger second concave ellipsoid mirror follows 3 , which is also arranged off-axis, specifically so that its entry focus F _E2 with the exit focus F _{A1 of} the first mirror 2 coincides. This will result in the exit side of the second mirror 3 a convergent light wavefront 4 provided with a relatively large opening ratio and a correspondingly large transverse dimension.

On the second ellipsoid mirror 3 an aplanatic-concentric meniscus lens follows before its exit focus 5 , in the example shown specifically in the form of a Fizeau lens. The latter reduces the focal length of the outlet and reduces the number of openings, ie it focuses that of the second ellipsoid mirror 3 coming light on one in front of the geometric exit focus of this mirror 3 actual light exit focus F _A.

At the same time, the Fizeau lens 5 With its exit-side surface, ie its concave side 5a, a reference surface is available for the respective interferometric measurement of a convex lens surface. For this purpose, the lens to be measured is placed at a suitable point opposite the reference surface 5a the Fizeau lens 5 positioned. The arrangement of the lens to be measured, the interferometric measurement process and the associated system components, in particular for evaluating the interference light, are all of a conventional type, as are customary from the standard measurement of convex lens surfaces for lenses of projection exposure systems in semiconductor technology. These components are therefore in 1 not shown explicitly and need no further explanation.

The two ellipsoid mirrors are an essential feature of the arrangement 2 . 3 , which lie opposite one another with their concave mirror surfaces off-axis to the optical axis, have a geometrically similar shape, ie they form sections of geometrically similar ellipsoids. In other words, the two ellipsoid mirrors belong 2 . 3 to ellipsoids of equal eccentricity.

It can be seen that the test optics designed in this way have the optical properties of systems for the interferometric measurement of convex lens surfaces, in particular with regard to aplanasia and field behavior and thus with regard to Sensitivity to drift, at least as well fulfilled as conventional inspection optics that use Aplanar lens arrangements of a correspondingly large diameter. In particular, this structure provides a compensating arrangement. In comparison to such conventional optics, the test optics shown can be implemented with significantly less effort.

Instead of several large-diameter lenses, there is only a single large-area optical element in the form of the second ellipsoid mirror 3 necessary and with the required accuracy. In addition, the two ellipsoid mirrors 2 . 3 can easily be checked interferometrically during their production, for example from a focal point against a spherical calibration mirror which has its radius center in the other focal point of the ellipse. In contrast, the convex sides of large lenses can often only be checked partially with test glasses by eye. As a further advantage of the omission of large lenses, the test optics shown avoid corresponding material problems, in particular with regard to stress birefringence and requirements for material homogeneity, such as occur with large lenses.

The test optics shown allow a low level Distance between it and the part generating the lighting wave the test system, this distance over a parallel beam with a small diameter of e.g. four inches can be varied as desired. Conventional large aplanar optics require a correspondingly large one Collimator for generating a parallel beam with a large diameter. The manufacture of the collimator is very complex. Although comes with huge Aplanar optics consider dispensing with the collimator if one uses a divergent entry wave for the aplanar optics. But this requires for the Aplanar design has even larger lens diameters and one is due to the fixed large distance between the input focus point and aplanar optics strong in the geometric design options of the test setup limited.

In a specific dimensioning, the inspection optics from 1 be designed for twelve inches with 0.8 opening. For this purpose, the aplanar lens on the inlet side has 1 eg a diameter of approximately four inches, the first ellipsoid mirror 2 a maximum used diameter of about 140mm to 150mm, the second ellipsoid mirror 3 a maximum used diameter of approx. 580mm to 600mm and the Fizeau lens 5 a diameter of approx. 320mm.

It goes without saying that other dimensions are possible depending on the application. As an example is in 2 12-inch inspection optics are shown, which are largely the same as those of 1 corresponds, but is dimensioned to an opening number of 0.57. For the sake of clarity, functionally equivalent elements are in the example of 2 with the same reference numerals as in 1 Mistake.

The opposite of the example of 1 even lower opening number of 0.57 for the exit-side light wave front 4 is used in the example of 2 achieved by the first ellipsoid mirror 2 to a maximum used diameter of approx. 210mm to 220mm and the second ellipsoid mirror 3 are dimensioned to a maximum used diameter of approx. 850mm to 860mm. On it is the Fizeau lens 5 suitably adapted in shape.

It is understood that the device according to the invention with the two concave, geometrically similar ellipsoid mirrors arranged off-axis 2 . 3 not only suitable as inspection optics for the interferometric measurement of convex lens surfaces, but can also be used wherever there is a need to provide a convergent light wavefront over a relatively large field with relatively large transverse dimensions. Furthermore, it goes without saying that the ellipsoidal mirrors do not necessarily have to have a mathematically exact ellipsoidal shape, rather an at least approximately ellipsoidal or elliptical shape is sufficient. The invention consequently also includes implementations in which the two mirrors have slight, image-optimizing deviations from the exact ellipsoid shape. The shape of the meniscus lens is suitably adapted to the selected mirror shape.

Claims (5)

Device for generating a convergent light wavefront ( 4 ), in particular for the interterometric measurement of convex lens surfaces, with - a first and a second aspherical mirror ( 2 . 3 ), which are arranged one after the other in the light beam path, the second mirror being a concave, at least approximately ellipsoidal mirror, characterized in that - the first mirror is a geometrically similar, concave, at least approximately ellipsoidal mirror to the second mirror ( 2 ), the two mirrors being arranged such that the exit focus (F _A1 ) of the first mirror coincides with the entry focus (F _E2 ) of the second mirror. Apparatus according to claim 1, further characterized in that the second mirror has a meniscus lens ( 5 ) follows. Device according to claim 1 or 2, further characterized by an entry-side focusing lens arrangement ( 1 ) to focus the light on the entrance focal point of the first mirror. Device according to one of claims 1 to 3, further characterized in that it relates to a exit-side number of openings for the generated convergent light wavefront of about 0.8 or less is dimensioned. System for the interterometric measurement of convex lens surfaces, characterized by - a device for generating a convergent light wavefront according to one of claims 2 to 4, wherein the concave side (5a) of the meniscus lens ( 5 ) serves as a reference surface for the interferometric measurement of a respective convex lens surface.