DE10304599A1 - Producing at least two lens arrangements for projection objective involves producing lens arrangements that are identical in basic structure and differ in lens material, apart from individual lenses - Google Patents

Abstract

The method involves producing at least two lens arrangements, whereby a first lens arrangement is configured for radiation of a first wavelength and at least one further lens arrangement is configured for radiation of a second wavelength. The lens arrangements are identical in their basic structure and differ in the lens material, apart from individual lenses.

Description

The invention relates to a method according to the preamble of patent claim 1.

There are, for example, projection lenses from US Pat. No. 5,990,926 and DE 18 91 8444 A1 with lens arrangements, which are designed for the wavelength 248 nm, are known.

A projection exposure system for microlithography is known from US Pat. No. 6,088,171 known. Several lens arrangements for projection lenses are known from this document, which are designed for an illumination wavelength of 193 nm.

Various projection objectives for microlithography are known from EP 1 139138 A1 known, which include lens arrangements, either for the wavelength 193 nm or for the wavelength is designed to be 157 nm.

For the construction of such projection lenses with such lens arrangements are of the Structure of the respective lens arrangement or dependent on the individual lens data Assembly structures required. Also on the lens data or on the individual Compatible test optics required.

Furthermore, different adjustment methods are dependent on the specific one Structure of the lens assembly required, which must be developed first and then be used in the construction of the respective lens arrangement. This too Adjustment procedures depend on the structure of the lens arrangement. Also for them Development and provision of the required inspection optics, assembly structures and Adjustment procedures require considerable development effort.

The object of the invention is the development effort for the provision or manufacture of projection exposure systems and in particular the lens arrangements for the Microlithography, which are designed for different illumination wavelengths, too to reduce.

The object of the invention is achieved by the features of patent claim 1. Through the Measure to provide a method by which two projection lenses or Lens arrangements which are designed for different wavelengths and which are characterized by Measure of the special selection of different lens materials from the Macroscopic structure could only differ minimally, the manufacturing and Development effort can be significantly reduced.

With individual corrections, it is possible to adjust the projection lens to the specific one provided lighting system, in particular on the wavelength of that Radiation emitted radiation to vote.

Due to the large degree of correspondence between individual components in the It is possible to use projection lenses for the different wavelengths identical frame parts in the projection lenses or in the lens arrangements for to use the at least two different wavelengths. This will make the Development effort for specially adapted frame parts reduced.

It has proven to be particularly advantageous if the diameters of corresponding lenses of the at least two lens arrangements differ for the different wavelengths by less than 1 mm and the curvature of the lens surfaces, in particular in the edge region, does not differ by more than 1 × 10 ^-5 l / mm , because it can then be guaranteed that identical lens frames can be used.

Also inspection optics, each for the inspection of individual optical elements or Components, especially lenses, must be developed and built for the review of the corresponding lenses and components aside from the used material are almost identical, are used.

Since the inspection optics for aspherical lens surfaces in particular are complex, it has turned out to be advantageous if, according to the optical data, identical aspherical Lens surfaces are provided.

It is also advantageous if the other lens surfaces are of the aspherical Lenses differ less than 5 µm and / or the lens thickness of the corresponding lenses not more than 5 mm, preferably not more than 1-2 mm or not differ by more than 5%.

It is particularly advantageous if the reciprocal values of the radii of the corresponding lenses differ less than 1 × 10 ^-4 mm ^-1 . If the corresponding radii of the lenses are less than 10,000 mm, it has proven to be advantageous if the reciprocal values of the radii differ by less than 5 × 10 ^-5 mm ^-1 , so that it can be guaranteed that a test lens for the characterization the corresponding lenses can be used.

It has proven to be advantageous if the number of openings of the respective corresponding lens surfaces differ less than 3%.

This means that the inspection optics required to provide the lens arrangements for the significantly reduced at least two different wavelengths. This results in one massive reduction in the manufacturing cost of the lens assembly and thus the respective projection objective, since of course the costs for the inspection optics also increase knock down the price of projection lenses.

The different lens materials used have proven to be advantageous to be selected such that the refractive index of the lens materials used at the first Projection lens for radiation of a first wavelength, the refractive index in the further Projection lens used materials at least at the further wavelength almost corresponds. Are different media for lenses and spaces between lenses provided, the quotient of the refractive indices of a lens is the quotient of the refractive index of the second lens.

Furthermore, it has proven advantageous to have identical assembly structures and / or Adjustment procedure for the construction of the projection lens or Use projection exposure systems for microlithography.

Further advantageous measures are described in further subclaims. in the The invention is described in more detail below using exemplary embodiments. It shows:

Fig. 1 projection exposure system;

Fig. 2 first projection lens for wavelengths of 351 nm;

Fig. 3 projection lens for wavelengths of 248 nm;

Fig. 4 projection lens for the wavelength of 193 nm; and

Fig. 5 corresponding projection lens for the wavelength of 157 nm.

The basic structure of a projection exposure system 101 , as used in microlithography, is first described with reference to FIG. 1. The projection exposure system 101 has an illumination system 103 and a first projection objective 105 . The projection objective 105 comprises a lens arrangement 119 with an aperture diaphragm AP, an optical axis 107 being defined by the lens arrangement 119 , 219 , 319 , 419 . A mask 109 is arranged between the illumination device 103 and the projection objective 105 and is held in the beam path by means of a mask holder 111 . Such masks 109 used in microlithography have a micrometer to nanometer structure, which is imaged on the image plane 113 reduced by a factor of 10, in particular by a factor of 4, by means of the projection objective 105 . A substrate or a wafer 115 positioned by a substrate holder 117 is held in the image plane 113 . The minimum structures that can still be resolved depend on the wavelength X of the light used for the illumination and on the aperture of the projection lens 105 on the image side, the maximum achievable resolution of the projection exposure system 101 increasing with decreasing wavelength of the illumination device 103 and with increasing aperture on the image side of the projection lens 105 .

In FIG. 2, the lens assembly 119 is shown of a first projection lens. The lens arrangement 119 is designed for radiation of a first wavelength of 351 nm. In comparison, a further lens arrangement 219 is shown in FIG. 3, which is designed for the illumination wavelength of 248 nm. The projection lens shown in FIG. 3 corresponds to the projection lens shown in FIG. 2. Corresponding here means that the lenses L arranged at the identical location in the respective objective 119 and 219 differ only slightly in the spatial arrangement and also in the surface shape.

The basic structure of a projection exposure system 101 in which the projection objective 219 shown in FIG. 3 can be used is shown in FIG. 1.

The structure of the lens arrangements 119 , 219 shown in FIGS. 2 and 3 is explained in more detail below. The numerical aperture of the projection objectives 105 designed for 351 mm and 248 mm is 0.75. The overall length from object plane 0 to image plane 0 'is 1000 mm for both lens arrangements 119 , 219 . Both lens arrangements consist of 31 lenses, which can be divided into six lens groups.

The first lens group LG1 each comprises the lenses with the lens surfaces 1-11 and has positive refractive power as a whole. The respective second lens group LG2 comprises the lenses with the lens surfaces 12-19 and has a negative refractive power as a whole. A waist is formed by this lens group LG2. The third lens group LG3 each comprises the lenses with the lens surfaces 20-31 and has positive refractive power overall. A second belly is formed by this lens group LG3. At this lens group LG3 is a fourth lens group LG4 includes at each / comprises the lenses of the lens surfaces 32 37th This lens group LG4 has an overall negative refractive power, a second waist being formed by this lens group.

The fifth lens group LG5 comprises the lenses with the lens surfaces 38-52 . This lens group LG5 has positive refractive power overall. A third belly is formed by this lens group LG5. A diaphragm is arranged after the lens with the lens surfaces 42 and 43 . The last lens group LG6 comprises the lenses with the lens surfaces 53-64 and has positive refractive power overall. This lens group LG6 has a collecting function.

With these projection lenses there is an image field with a diameter of 27.203 mm exposable.

In the lens arrangement 219 shown in FIG. 3, all lenses are made of quartz glass, which has a refractive index of 1.50839641 compared to normal air at a predetermined temperature, for example 22 ° C. Air at 950 mbar is provided as the medium between the lenses, which at the predetermined temperature has a refractive index of 0.99998200 compared to normal air. What is decisive for the course of the beam path is how the ratio of the refractive indices of the two media, lens material to the medium between the lenses, is to one another. The reference to normal air is irrelevant, only the media's refractive index quotient is decisive.

Starting from the projection lens according to FIG. 3, which is designed for the wavelength 248.34 nm, it was possible by a clever choice of material or choice of media for the lenses and the interstices between lenses, a further projection lens for a different illumination wavelength, here from 351, 14 nm, with minimal development effort. In this specific case, the material FK5 has been selected for the lenses for a desired illumination wavelength of 351 nm. At an illumination wavelength of 351.14 nm, this material FKS has a refractive index of 1.50623 compared to normal air under the predetermined conditions of temperature and pressure. Air at 950 mbar was again chosen as the medium between the lenses. In order to improve the performance, minor modifications have been carried out which cannot be seen with the naked eye when comparing the lens sections 119 , 219 . Both lens arrangements 119 , 219 have comparable good optical properties with a numerical aperture of 0.75 on the image side.

The refractive indices of the different lighting wavelengths, here 248 mm and 351 nm, should not differ by more than 0.2%. The refractive indices can also be matched in that the refractive index of the intermediate medium is carried out, for example, by selecting a different gas or a different pressure. The refractive indices can also be adjusted by selecting different temperatures at which the projection objectives 105 are to be operated or the lens arrangements 119 , 219 are used. It is also possible to manufacture a slightly modified FK5 material so that the difference in refractive index is almost fulfilled.

The exact lens data for the projection lens shown in FIG. 2 can be found in Table 1. TABLE 1

The exact lens data of the projection objective shown in FIG. 3 can be found in Table 2. TABLE 2

Special test arrangements and test procedures are from the German applications DE 10 00 5171.5, DE 10 00 5172.3 and DE 10 00 7170.7 are known, which expressly for Disclosure contents of this application include.

The deviations in the lens data of the corresponding lenses from the projection objectives shown in FIGS . 2 and 3 can be seen from the table below. Table 3

The numbering of the areas is given in the first column, so that they are unique Allocation to the respective areas is possible.

The second column shows the difference between the reciprocal values of the radii. There the differences determined are very small, is the difference determined with the factor 100,000 has been multiplied.

A comparison of the lens thicknesses is given in the third column. To represent the Deviation of the lens thickness, the quotient of the lens thickness has been formed, whereby the greater value of the two thicknesses to be compared has always been set in the counter is such that the value of the quotient thus formed always gives a value that is greater than 1 is. The value 1 was then subtracted from this value. Because here too Thickness differences determined in this way were very small, the value is multiplied by 1000 Service.

The ratios of the S free diameters were determined in the same way as the thickness ratios. The values of the thickness ratios are listed in column 4 .

As can be seen from Table 3, the absolute deviation of the lens curvature is smaller than 10 × 10 ^-5 mm ^-1 in at least 95% of the lenses. In particular, if the deviation of the free diameter of the lenses or the difference in the absolute diameter of mine is less than 1 mm, the same frames can generally be used. If the deviation is a little larger, only the contact surface is adjusted. The intermediate rings then vary depending on the curvature of the lens.

It has proven to be particularly advantageous in the corresponding Lens arrangements to provide identical aspherical lens surfaces. Just that Aspheres require a complex test set-up, so that alone an enormous cost reduction is achieved due to this measure.

If the reciprocal values of the radii deviate less than 5 × 10-5 mm ^-1 from one another with spherical lens surfaces with a radius amount <1000 mm, then identical inspection optics can be used to check the curvature of the lens surface. The test optics are then designed for the lens that is more demanding in terms of aperture and focal length.

The adjustment methods are particularly dependent on axial and lateral sensitivities and must be varied widely, especially depending on lens curvatures. There in the previous example, the projection lenses have only slight deviations in the have parameters relevant for the adjustment process are identical adjustment procedures applicable.

In Figs. 4 and 5 two non macroscopically distinctive lens arrays 319, 419 are shown. The lens arrangement 319 shown in FIG. 4 is designed for the illumination wavelength of 193 nm. The lens arrangement 419 shown in FIG. 5 is designed for the illumination wavelength of 157 nm, the lenses of this design being stored in a nitrogen environment. Both lens arrangements 319 , 419 have a numerical aperture of 0.85 at the respective illumination wavelength. The overall length from image plane 0 'to object plane 0 is 1000 mm. With these lens arrangements 319 , 419 , an image field with a diameter of 28.04 mm can be exposed. These lens arrangements 319 , 419 comprise 29 lenses which can be subdivided into six lens groups LG1 to LG6.

The first lens group LG1 comprises the positive lenses with the lens surfaces 2-7 . The lens surfaces 2 and 4 are each aspherized. This lens group has positive refractive power overall. This first lens group LG1 is followed by a second lens group LG2, which has negative refractive power and through which a first waist is formed. This lens group LG2 comprises the lenses with the lens surfaces 8-13 . The lens surfaces 8 and 13 are each aspherized. The third lens group LG3 comprises the lenses with the lens surfaces 14-23 , the lens surface 23 being aspherical. A belly is formed by this lens group LG3. This lens group LG3 has positive refractive power overall. The adjoining fourth lens group LG4 has an overall negative refractive power. A second waist is formed by this lens group LG4. This lens group includes the lenses with the lens surfaces 24-31 . The fifth lens group LG5 comprises the lenses with the lens surfaces 31-39 and 41-48 in this lens group an aperture 40 is arranged. This lens group has positive refractive power. The last lens group LG6 also has positive refractive power and comprises the lenses with the lens surfaces 49-60 .

In the lens arrangement 319 shown in FIG. 4, quartz glass is provided as the lens material. The space between the lenses is filled with air at 950 mbar. Quartz glass has a refractive index of 1.56028895 at the illumination wavelength of 193 nm. The air between the lenses has a refractive index of 0.99998200 compared to standard air under the predetermined conditions. The normal air is based on a pressure of 1013.25 mbar and 20 °.

The lenses of the lens arrangement 419 shown in FIG. 5 are made of the material calcium fluoride, which has a refractive index of 1.55929035 at an illumination wavelength of 157.6 nm. The space between the lenses is filled with nitrogen, which at 157.6 nm has a refractive index of 1,000,31429 compared to standard air.

Through this targeted selection of the media for the lenses and the gaps, the design of a lens arrangement 319 for 193 nm could be transferred to an illumination wavelength of 157 nm, the optical properties of the lens arrangement 419 having been further improved by means of minimal modifications.

The quotient of the refractive index of quartz glass and air is 1.560317036 at 193 nm. The The quotient of the refractive indices of calcium fluoride and helium is 1.558800435 at 157 nm. The refractive index ratios of the lens for 193 nm thus differ from that for 157 nm designed lens by 0.0973% from each other.

The refractive indices or the refractive index of the lens material and the gas present between the lenses in relation to each other d. H. Refractive index of nitrogen in the Reference to calcium fluoride in relation to the refractive index of air at 950 mbar to the refractive index not differ from quartz glass by more than 0.2%.

This ensures that minor modifications can also be made to the Lens arrangement of a first illumination wavelength derived lens arrangement for use at a further illumination wavelength with excellent optical Has properties.

Of course, it is also possible to allow a larger difference in the refractive indices, however, this has the disadvantage that larger deviations are required or the optical properties of the derived lens arrangement are not quite as good are. This may result in poorer optical properties of the Projection lens in which the lens arrangement is used.

The exact lens data from the projection lens shown in FIG. 4 can be found in Table 4 below. TABLE 4

The exact lens data of the projection lens shown in FIG. 5 can be found in Table 5. TABLE 4

The following table 6 shows the radius differences and the thickness differences and the deviations of the free diameters, which were determined according to the same calculation rules as in table 3.

The exemplary embodiments shown by FIGS. 2 to 4 serve to illustrate the invention, the invention being not restricted to these exemplary embodiments.

From these exemplary embodiments it can be seen in particular that it is advantageous if the radius of the aspherical lens surface of the corresponding lenses does not differ from one another by more than 0.1 mm or the reciprocal of the radii does not differ from one another by more than 1.10 ^-6 l / mm. For the spherical lens surface of the aspherical lens, the reciprocal of the radius does not differ by more than 5 × 10-6 mm ^-1 . The thicknesses of the corresponding aspherical lenses differ less than 0.5 mm absolute or less than 3% from each other.

Claims (9)

1. A method for providing at least two lens arrangements for a projection objective, a first lens arrangement being designed for radiation of a first wavelength and at least one further lens arrangement for radiation of a different wavelength, characterized in that the basic arrangement of the lens arrangements ( 105 ) is identical and, apart from individual lenses, differ in the lens material used. 2. The method according to claim 1, characterized in that two lens arrangements are identical in their basic structure with respect to the surface curvature if the lenses of the first ( 219 , 319 ) and further lens arrangement ( 119 , 419 ) corresponding in the basic structure are less in the reciprocal of their radius differentiate as 5.5 × 10 ^-5 mm ^-1 . 3. The method according to claim 1 or 2, characterized in that two lens arrangements ( 219 , 319 and 119 , 419 ) are identical in their basic structure with respect to the center thicknesses of the lenses when the corresponding lenses are not more than 5%, preferably around less than 1%. 4. The method according to any one of claims 1-3, characterized in that at least 60% of the lenses (L) used in the lens arrangement ( 119 , 219 , 319 , 419 ), apart from the lens material used, are identical in their basic structure. 5. The method according to any one of claims 1-4, characterized in that specially adapted frame parts are used in the first lens arrangement ( 219 , 319 ) and in the further lens arrangement ( 119 , 419 ). 6. The method according to at least one of the preceding claims, characterized in that the first lens arrangement ( 219 , 319 ) and the further lens arrangement ( 119 , 419 ) are constructed using identical assembly structures and / or adjustment methods. 7. The method according to claim 1, characterized in that the optical properties of 95% of the optical elements (L), which are used in the lens arrangements ( 119 , 219 , 319 , 419 ), can be characterized using the same inspection optics. 8. The method according to any one of the preceding claims, characterized in that the lens data of aspherical lens surfaces of the corresponding lens arrangements ( 219 , 119 and 319 , 4 ) match. 9. Manufacturing method of a first and a further projection objective or a first and a further projection exposure system for microlithography, which are each designed for different wavelengths and have different lighting systems ( 103 ) for providing the radiation, characterized in that the lighting systems ( 103 ) lens arrangements ( 119 , 219 , 319 , 419 ) for the respective illumination wavelength are respectively assigned, which were generated according to one of claims 1-8.