KR20180008494A - Pupil facet mirror - Google Patents

Abstract

It is an object of the present invention to improve a pupil facet mirror for an illumination optical unit of a projection exposure apparatus. The essence of the present invention is to form a pupil facet mirror 20 having pupil facets 29 of different sizes. The pupil facet 29 may have a particularly different shape. At least the subset of pupil facets may have an irregular shape. They have particularly different lengths of side edges. They have the form of irregular polygons in particular.

Description

Pupil facet mirror

The contents of German patent application DE 10 2015 209 175.9 are incorporated herein by reference.

The present invention relates to a pupil facet mirror for an illumination optical unit of a projection exposure apparatus. The invention also relates to a method for determining the design of a pupil facet mirror. The present invention also relates to an illumination optical unit for a projection exposure apparatus having a corresponding pupil facet mirror, an optical system having such illumination optical unit, and a projection exposure apparatus having an illumination system and a corresponding illumination optical unit. Finally, the present invention relates to a method of making microstructured or nano-structured parts and parts made according to the method.

Lighting optics units with facet mirrors are known, for example, from US 2011/0001947 Al, US 2013/0335720 Al and US 6,859,328 B2.

It is an object of the present invention to improve the pupil facet mirror of the illumination optical unit of the projection exposure apparatus. This object is achieved by a pupil facet mirror according to claim 1. The gist of the invention is to form a pupil facet mirror with pupil facets of different sizes. The pupil facet can have a particularly different shape. At least a subset of the pupil facets may have a non-uniform form. This has, in particular, a different length of side edge. This can especially be in the form of an irregular polygon.

In the case of forming a pupil facet in n-gon, that is, when forming reflection surfaces of n corners, the shape of the reflection surface has m-fold rotational symmetry, where m < The shape of the reflecting surface is particularly simply a trivial one-fold rotational symmetry. In the case of a hexagonal pupil facet, this configuration may have a one-fold, two-fold, or three-fold rotational symmetry.

In one aspect of the invention, such a subset of pupil facets with irregular morphology is particularly advantageous for at least 10%, especially at least 20%, in particular at least 30%, in particular at least 40%, in particular at least 50% %, In particular at least 70%, in particular at least 80%, in particular at least 90%. It is also possible to form all the pupil facets having an irregular shape. It is also possible to set an upper limit for the number of irregularly shaped pupil facets. The upper limit can be, for example, 90%, 80%, 70%, 60%, 50%, 40%, 30%, 20% or 10%.

According to the present invention, the overexposure of the facet of the pupil facet mirror is effected in the form of a spot, i. E., The shape and / or size of the pupil facet in the form of the image of the source generated by the facet of the first facet mirror on the facet of the pupil facet mirror It has been found that adaptation can be reduced, in particular minimized, in particular avoided. This allows the transmission of the illumination system to be maximized. In this way it is possible to improve the stability of the illumination system, especially with regard to possible drift during operation.

The term pupil facet mirror serves to distinguish it from the first facet mirror of the illumination optical unit arranged in front of the path of the beam of illumination radiation, also referred to primarily as the field facet mirror. The first facet mirror is preferably disposed in the field plane of the illumination optical unit that is conjugate with the object field. However, it may also be arranged away from such a field plane. And is preferably arranged in the vicinity of the corresponding field plane.

The pupil facet mirror, generally referred to as the second facet mirror, is preferably arranged in the pupil plane of the illumination optical unit. It may also be arranged away from such a pupil plane. But is preferably disposed adjacent to the pupil. For a more precise and quantitative definition of the term pupil adjacency, see DE 10 2012 216 502 A1.

The mirror element of the pupil facet mirror, referred to as the pupil facet, is particularly well-arranged. No actuating mechanism for displacing the mirror element is required. As a result, the structure of the pupil facet mirror is considerably simplified.

According to an aspect of the invention, the size of the at least two mirror elements of the pupil facet mirror is different by a factor of at least 1.05, in particular at least 1.1, in particular at least 1.15, in particular at least 1.2. It should be understood that the size of the mirror element means here the area content of the reflective surface. The size of the mirror element is preferably different by a factor of up to 2, in particular up to 1.5, in particular up to 1.3.

The mirror element of the pupil facet mirror has in particular a polygonal individual reflecting surface. The adjacent mirror elements preferably have reflective surfaces with side edges that extend parallel to one another. In particular, the side edges of adjacent two mirror elements which are adjacent to each other advance in parallel. This increases the degree of filling of the pupil facet mirror.

According to another aspect of the present invention, the pupil facet mirror has a high degree of filling. The degree of filling is also referred to as the degree of integration. In particular at least 0.7 °, in particular at least 0.8 °, in particular at least 0.9 °. The high degree of filling has the effect of reducing transmission losses, especially avoiding them.

According to a further aspect of the invention, the individual reflecting surfaces of the mirror elements are arranged in each case by a parallel displacement of at least one of the side edges, in particular up to 12, in particular up to 10, in particular up to 8, In each case from a basic form selected from a maximum of five, in particular a maximum of four, in particular a maximum of three, in particular a maximum of two different basic forms, with the form In particular, each individual reflecting surface may have the form of expanding from the same shape each by a parallel displacement of at least one side edge.

A convex basic shape having an arc-shaped sectional shape edge, in particular a polygon or a polygon in general, is used as a basic shape. In particular, an isosceles polygon, especially a regular polygon, can be used in a basic form. The polygon can be in particular a triangle, a rectangle, a pentagon, a hexagon or an octagon. The basic form is particularly chosen so that the plane can be parquet with it. This can take the form of a general parqueting of planes or, in particular, the form of demiregular, semiregular or square fitting.

The shape of the individual reflecting surfaces develops in the direction of an individual center perpendicular to the edge or in the case of an arcuate edge with a displacement of one or more of its edges in the direction of the center vertical through the line touching the two corner points . In other words, the basic form of the cabinet is maintained during displacement. As a result, on the one hand, the design of the pupil facet mirror is facilitated. In addition, the creation and / or treatment of the pupil facets is consequently facilitated. The occurrence of unwanted voids between the individual mirrors can be consequently avoided.

Displacement of one edge of one of the mirror elements can simultaneously cause displacement of the adjacent edge of the adjacent mirror element. This will be described in more detail below.

In a further aspect of the present invention, at least some of the individual reflective surfaces are hexagonal. In particular, it is contemplated that all individual reflective surfaces are formed in hexagonal shape. The hexagonal shape of the individual reflective surfaces enables the fracturing to be made substantially without any gap.

The interior angle of the individual reflecting surfaces can be in particular 120 [deg.] In each case. Alternatives are possible. For example, the individual reflecting surfaces may also be formed in the form of a parallelogram. Other types of combinations are possible, such as parallelograms and pentagons.

In a further aspect of the invention, the mirror element is arranged on a grid point of a rectangular grid, in particular a hexagonal grid. The mirror element is arranged such that, before adaptation, the geometric center of its reflecting surface lies at the grid point of the rectangular hexagonal grid.

In an alternative embodiment, the mirror element is arranged such that the geometric center of its reflecting surface before adaptation is systematically distorted along one direction, especially at the grid point of the systematically distorted hexagonal grid along one direction .

In other words, the pupil facets are particularly arranged on the pupil facet mirror based on the circle's most dense packing, i.e., a hexagonal grid. For the adaptation of the pupil facets to the spot shape, it is particularly conceivable to change the shape and size of the adjacent pupil facets based on this arrangement by the paired displacements of the side edges parallel to one another. This will be described in more detail below.

In one aspect of the invention, in particular, the size of the individual reflecting surfaces is defined to have systematic scaling according to the paired individual deformations of adjacent individual reflecting surfaces and / or the position of the mirror element on the pupil facet mirror .

The structured scaling of the size of the individual reflective surfaces allows the inclination of the pupil facet mirror relative to the plane to be parallel to the object plane to be taken into account. The systematic scaling relates specifically to the basic form of the individual reflective surfaces of the mirror elements.

The size L of one of the individual reflective surfaces along the distortion direction may in particular be characterized by the following estimate: 0.9 (d / d _ref )? L: L _ref? 1.1 (d / d _ref ) ², in particular _{0.95 (d / d ref) ²≤L} : L ref ≤1.05 (d / d ref) ², in particular _{0.97 (d / d ref) ²≤L} : L ref ≤ 1.03 (d / d ref) ² , Especially 0.99 (d / d _ref ) ² L: L _ref ≤1.01 (d / d _ref ) ², especially 0.995 (d / d _ref ) ≤ L: L _ref ≤1.005 (d / d _ref ) ². Where d denotes the distance of the individual facets from the reticle, in particular the optical path. L _ref and d _ref denote any desired reference facets, e.g., the minimum facets.

Certain forms of the individual individual reflective surfaces may be affected by the paired individual variations of adjacent individual reflective surfaces. The displacement of the two parallel edges of the adjacent mirror elements provided in accordance with the invention has the effect, in particular, that the size of the individual reflecting surfaces of one mirror element is increased at the expense of the size of the individual reflecting surfaces of the mirror elements which are individually different. As a result, improvements in the transmission, especially in the maximization of the transmission, are possible.

It is a further object of the present invention to improve the method for determining the design of the pupil facet mirror. This object is achieved by a method comprising the steps of:

In particular, according to claim 1, there is provided a method comprising: defining a basic shape selected from a group of up to five different basic shapes having a maximum of 12 side edges for the shape of individual reflective surfaces of mirror elements of a pupil facet mirror;

Adapting the size and / or shape of the individual reflective surfaces to improve transmission and / or system stability,

Paired individual transformations and / or structured scaling of adjacent individual reflecting surfaces provided for adaptation of size and / or shape of individual reflecting surfaces.

The adaptation of the size and / or shape of the individual reflective surfaces allows the transmission and / or system stability to be improved.

The paired deformation of adjacent individual reflecting surfaces should be understood to mean, in particular, as described above, that the size of the individual reflecting surfaces is increased at the expense of the size of the adjacent individual reflecting surfaces by displacing one of the side edges thereof .

In a further aspect of the invention, it is contemplated to displace the parallel edges of the adjacent mirror elements in pairs to accommodate the size of the individual reflective surfaces. The other mirror elements can be held unchanged by this.

In a further aspect of the present invention, it is contemplated to consider the adaptation of the size of the individual reflective surfaces to the intensity distribution of the illumination radiation in the array of mirror devices and / or the area of the individual reflective surfaces of the illumination optical unit.

According to the invention, it has been found that the imaging characteristics of the collector and the possible spectral filtering surface structures on the collector can cause an ellipticity of the illumination spot on the pupil facet mirror due to the anisotropy of the radiation source, especially due to the anisotropy of the plasma. This may involve specifically changing the orientation of the illumination spot over the far field. The location, size and shape of the illumination spot can be determined by simulation or experimentally. In particular, this can be determined, especially calculated from the data of the radiation source and / or the illumination optical unit.

It has also been found that the distortion of the grid for the arrangement of the pupil facets can be caused by the inclined arrangement of the pupil facet mirror relative to the plane parallel to the object plane. This can be considered in the design of the pupil facet mirror.

It is also an object of the present invention to improve an illumination optical unit for a projection exposure apparatus, an illumination system for the projection exposure apparatus, an optical system for the projection exposure apparatus, and a corresponding projection exposure apparatus.

These objects are each achieved by a pupil facet mirror according to the above description.

The advantage is clear from the advantages of the pupil facet mirror.

According to another aspect of the invention, an EUV radiation source, i.e. a radiation source emitting radiation radiation in the EUV range, in particular in the wavelength range of 5 nm to 30 mm, serves as the radiation source.

It is a further object of the present invention to improve methods of manufacturing microstructured or nanostructured components and improving such components. This object is achieved by providing a projection exposure apparatus according to the present invention. Advantages are evident from the advantages described above.

This part can be produced with a very high structural resolution. In this way, it is possible, for example, to manufacture semiconductor chips with very high integration or storage density.

Other advantages, details and details of the present invention will become apparent from the description of exemplary embodiments with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 schematically shows the zonal cross section of a projection exposure apparatus for EUV projection lithography.
Figures 2 and 3 illustrate an array variation of a field facet mirror that may be implemented with a monolithic field facet, but which may also have a field facet constructed in each case from a plurality of discrete mirrors.
4 schematically shows a plan view of a pupil facet mirror which is part of an illumination optical unit of a projection exposure apparatus, together with a field facet mirror.
Figure 5 shows an exemplary embodiment of a variation of the edge contour of the partial beam of illumination light impinging on the pupil facet by exactly one of the field facets, which can be used in the case of the pupil facet mirror shown in Figure 4 Wherein the defined illumination channel is presented on the pupil facet and the field dependent center profile of the illuminating light sub-beam diverging from different points on the associated field facets during imaging of the light source, in addition to the edge contour of the illuminating light partial beam Are presented.
FIG. 6 is a graphical representation of the system distortion from the view point of the object field point in the equidistant direction of the pupil facet mirror induced by the tilt of the pupil facet mirror with respect to the plane parallel to the object field plane. Fig.
Figure 7 shows a schematic diagram for describing a paired individual variation of the size of adjacent individual reflective surfaces provided in accordance with the present invention.
Figure 8 schematically shows a top view of a partial area of a pupil facet mirror according to an alternative embodiment.

Fig. 1 schematically shows a meridional section of a microlithographic projection exposure apparatus 1. Fig. The projection exposure apparatus 1 includes a light or radiation source 2. The illumination system 3 of the projection exposure apparatus 1 has an object field 5 of the object plane 6 and an illumination optical unit 4 for exposing the illumination field.

The illumination field may also be larger than the object field 5. In this case, an object in the form of a reticle 7 arranged by the object field 5 and held by the object or reticle holder 8 is exposed. The reticle 7 is also referred to as a lithography mask. The object holder 8 is displaceable along the object displacement direction by the object displacement drive 9. [ The projection optical unit 10, which is shown quite schematically, serves to image the object field 5 into the image field 11 of the image plane 12. The structure on the reticle 7 is imaged on the photosensitive layer of the wafer 13 arranged in the region of the image field 11 of the image plane 12. [ The wafer 13 is held by the wafer holder 14. The wafer holder 14 is displaceable in parallel with the object displacement direction together with the object holder 8 by the wafer displacement drive 15. [

The radiation source 2 is an EUV radiation source emitting radiation in the range between 5 nm and 30 nm. For example, a plasma source such as a gas discharge-produced plasma (GDPP) source or a laser-produced plasma (LPP) source. A source of radiation based on a synchrotron or free electron laser (FEL) may also be used as the source 2. Information about such radiation sources is known to those skilled in the art, for example from US 6,859,515 B2. The used illumination light for illuminating the EUV radiation 16, in particular the object field 5, originating from the radiation source 2 is focused by the concentrator 17. [ A corresponding concentrator is known from EP 1 225 481 A. Downstream of the concentrator 17 the EUV radiation 16 propagates through the intermediate focal point 18a of the intermediate focal plane 18 before it is incident on the field facet mirror 19. The field facet mirror 19 is a first facet mirror of the illumination optical unit 4. The field facet mirror 19 includes a plurality of reflective field facets 25, which are shown schematically in FIG.

The field facet mirror 19 is arranged in the field plane of the illumination optical unit 4 which is optically conjugate with respect to the object plane 6. [

EUV radiation 16 will be referred to hereinafter as illumination radiation, as illumination light, or as imaging light.

Downstream of the field facet mirror 19, the EUV radiation 16 is reflected by the pupil facet mirror 20. The pupil facet mirror 20 is a second facet mirror of the illumination optical unit 4. The pupil facet mirrors 20 are arranged in the pupil plane of the illumination optical unit 4 and are arranged in the pupil plane of the illumination optical unit 4 with respect to the intermediate focal plane 18 and with respect to the pupil plane of the projection optical unit 10, Or coincides with this pupil plane. The pupil facet mirror 20 has a plurality of reflective pupil facets as shown schematically in FIG. The pupil facet 29 has in each case a reflecting surface 33, also referred to as an individual reflecting surface. Clearly, the reflecting surface 33 itself is referred to as the pupil facet 29. The pupil facet 29 of the downstream imaging optical assembly in the form of a pupil facet mirror 20 and a transmission optical unit 21 having mirrors in the beam path order 22, 23 and 24, Are used to image the object field 5 and are superimposed on each other. The last mirror 24 of the transmission optical unit 21 is a grazing incidence mirror. According to the configuration of the illumination optical unit 4, it is also possible to omit the transmission optical unit 21 in whole or in part.

Toward an absolute x-value greater than the x-dimension of the object field 5, the illumination light 16 guided in the object plane 6, for example, is guided by a plurality of energies (not shown) Or a dose sensor (one of these dose sensors 24a is shown schematically in Figure 1). The dose sensor 24a is in signal connection with the central control device 24b in a manner not shown. The dose sensor 24a generates an input signal to control the light source 2 and / or the object displacement drive 9 and / or the wafer displacement drive 15. [ By doing so, it is first possible to achieve a dose adaptation of the exposure of the wafer 13 of the image field 11 by first adapting the output of the light source 2 and / or adapting the scanning speed in turn.

The control device 24b is in signal connection with the tilt actuator to the field facet 25 of the field facet mirror 19, among others.

To simplify description of the positional relationship, Fig. 1 shows an example of a global coordinate system for describing the positional relationship of the components of the projection exposure apparatus 1 between the object plane 6 and the image plane 12, and an orthogonal xyz- . The x-axis extends perpendicularly in FIG. 1 into the plane of the drawing. In Fig. 1, the y-axis extends parallel to the right side in the displacement direction of the object holder 8 and the wafer holder 14. The z-axis extends downward in Fig. 1, i.e. perpendicular to the object plane 6 and the image plane 12.

The x-dimension for the object field 5 or the image field 11 is also referred to as the field height. The object displacement direction extends parallel to the y-axis.

In further figures, a local orthogonal xyz-coordinate system is shown. The x-axis of the local coordinate system extends parallel to the x-axis of the global coordinate system according to Fig. The xy-plane of the local coordinate system represents the array plane of the element provided in the figure, respectively. The y- and z-axes of the local coordinate system are accordingly inclined to each x-axis up to a certain angle.

Figures 2 and 3 illustrate examples of different facet arrangements for the field facet mirror 19. Each of the field facets 25 presented herein can be configured as a separate mirror group from a plurality of individual mirrors, for example as is known from WO 2009/100 856 A1. Each one of the individual-mirror groups has the function of a facet mirror facet as disclosed in US 6,438,199 B1 or US 6,658,084 B2 at this time.

In operation, the field facets 25 can be configured to be tilted between a plurality of inclined positions by an actuator.

The field facet mirror 19 according to FIG. 2 has a plurality of arcuately configured field facets 25. These are arranged in a group by the field facet block 26 on the field facet carrier 27. Overall, the field facet mirror 19 according to FIG. 2 includes 26 field facet blocks 26, where 3, 5, and 10 of the field facets 25 are grouped together.

A gap 28 is present between the field facet blocks 26.

The field facet mirror 19 according to Fig. 3 comprises a rectangular field facet 25, these facets are arranged in groups in the field facet blocks 26, and there is a void 28 between the blocks.

Fig. 4 schematically shows a detailed plan view of the pupil facet mirror 20. Fig. The pupil facets 29 of the pupil facet mirror 20 are arranged in the region of the illumination pupil of the illumination optical unit 4. [ In practice, the number of pupil facets 29 can be much greater than the number of field facets 25 and a multiple of the number of field facets 25. The pupil facet 29 is arranged on the pupil facet carrier 30 of the pupil facet mirror 20. The distribution of the pupil facets 29 that collide with the illumination light 16 through the field facets 25 in the illumination pupil provides the actual illumination angular distribution of the illumination pupil, i.e., the object field 5.

The pupil facets 29 all have a hexagonal shape. In particular, it has only an internal angle of 120 [deg.].

Each of the field facets 25 serves to transmit a portion of the illumination light 16, i.e., the illumination light partial beam 16 _i , from the light source 2 toward one of the pupil facets 29.

From below, the illumination light beam portion of a substrate (16 _i), associated field facet 25 is assumed to be the maximum extent in each case, that is, lights against the total reflection surface. In this case, the edge contour of the illumination light partial beam 16 _i coincides with the edge contour of the illumination channel, and for this reason the illumination channel is also denoted as 16 _i below. Each light channel (16 _i) are, with additional components of the illumination optical unit 4, it shows a possible section of the optical path of the illumination light beam (16 _i) for illuminating an associated field facet 25 to the maximum extent.

Of each light channel for (16 _i), passes the optical unit 21, respectively, illumination light part beam (16 _i) of the field facets 25, the pupil facets (29) to pass towards the object field (5) from One.

In each case, two illumination light partial beams _16i (i = 1, ..., N, where N is the number of field facets) are schematically shown in Fig. 1 and one illumination light partial beam 16 _i is guided between the light source 2 and the object field 5 through exactly one of the field facets 25 and exactly one of the pupil facets 29 through one illumination channel in each case.

Figure 5 shows one of the pupil facets 29 that can be used for the pupil facet mirror 20. The pupil facet 29 according to FIG. 5 has a hexagonal edge contour with a side edge 32. The facet 29 shown in Fig. 5 has the shape of a regular hexagon. In the pupil facet mirror 20 shown in detail in FIG. 4, this serves as a basic form for all the pupil facets 20. Such an edge contour makes it possible to cover the pupil facet carrier 30 densely or at least as compactly as possible by the pupil facet 29. The pupil facet mirror 20 has a filling degree of at least 0.6, in particular at least 0.7, in particular at least 0.8, in particular at least 0.9. Such an edge contour makes it possible to cover the pupil facet carrier 30 densely or at least as compactly as possible by the pupil facet 29.

Illumination light beam portion (16 _i) is impinging on the pupil facets 29 according to Figure 5 by the arcuate field facets 25 of the field facet mirror 19 shown in Fig.

5, the entire cross-section of the illumination light partial beam 16 _i is located on the pupil facet 29 so that the illumination light partial beam 16 _i is incident on the edge of the pupil facet 29 It is not cut off in the vicinity. The edge profile of the cross section of the illumination light partial beam 16 _i on the pupil facet 29 has a substantially arc-shaped, bean-like or kidney-like shape, and has a round source area of the light source 2 It can be understood that the convolution of the arcuate field facets 25 shown in Fig. The convolution, in the different sections on the light source 2, the image is related to the field facets (25), that is, the field-dependent manner, in different image locations, and additional pupil generally along an illumination channel (16 _i) by Is formed at the image position that is spaced from the facet 29, i. E., Lying in the beam path, upstream or downstream of the pupil facet 29. [

Arc-shaped contour of the edge portion of the illumination light beam (16 _i) on the pupil facets 29 denotes a light spot of the illumination light beam portion (16 _i). The light spot of the illumination light partial beam 16 _i on the pupil facet 29 is also referred to as an illumination spot, and the shape whose range is defined by its edge contour is referred to as a spot shape.

These sub-beams 16 _i ¹ , 16 _i ² , ..., 16 _i ^x are indicated using dotted lines at the edge contour of the illumination light partial beam 16 _i on the pupil facet 29. The illumination light partial beam 16 _i consists of a number of such sub-beams 16 _i ^j . Illumination light beam portion (16 _i) on the one, the individual pupil facets (29) to know the optical parameters of the light, for example, be calculated using the optical design program, and is also referred to as "point spread function" with respect to this.

The illumination light 16 of these sub-beams 16 _i ¹ to 16 _i ^x diverges from a different point 25 ⁱ of the associated field facet 25. In FIG. 2, divergence points 25 ¹ , 25 ^2, and 25 ^x are shown in an exemplary manner on one of the field facets 25.

The field-dependent center profile 31 _{i of} all the sub-beams 16 _i ^j diverging from the associated field facets 25 is defined by the edge contour of each illumination-light partial beam 16 _i on each pupil facet 29, Of the kernel. The central profile (31 _i) is divided according to each light channel (16 _i), inter alia, relating to the field facets (25) light channel (16 between the light source (2) and each pupil facet 29 through _i &_lt; / _RTI &gt;

Figure 5 shows the idealized (idealized) field-dependent central profile (31 _i).

Additional aspects of the field facet mirror 20 are described below.

5, the illumination spot is at a different distance from the side edge 32 of the pupil facet 29. As shown in FIG.

In the present invention, it has been found advantageous to achieve the highest possible resolution when the illumination pupil has the lowest possible fill degree. Here, it is advantageous to create as small a pupil facet 29 as possible. On the other hand, the pupil facet 29 should not be too small, since there is overexposure and consequently undesired transmission losses. To reduce, specifically minimize, transmission losses, the pupil facets 29 are arranged as densely packed as possible.

As described below, it is envisioned that in accordance with the invention, adapted to the size and / or shape of the pupil facets 29, the spot shape of each illumination light beam portion (16 _i). As a result, the overexposure of the pupil facet 29 can be reduced, in particular minimized, and in particular avoided, and consequently the transmission of the illumination system 3 is increased, in particular maximized. The maximum and exposure of the pupil facet 29 is at most 20%, in particular at most 10%, in particular at most 5%. This depends in particular on the details of the source 2.

Also, the degree of filling can be reduced, especially minimized, and thus the resolution is increased by the adaptation of the size and / or shape of the pupil facet 29 to the spot form of the individual illumination light partial beam 16 _i .

In order to determine the size and / or shape of the pupil facet 29, a pupil facet 29 is densely packed on the pupil facet mirror 20 based on the roundest most dense packing, i. E. As shown in FIG. Based on this arrangement of the homogeneous, in particular regular, pupil facets 29, the shape and / or size of the individual pupil facets 29, in particular their reflecting surfaces 33, is adapted. In the adaptation of the shape and / or size of the reflecting surface 33 of the pupil facet 29, the individual partial beams 16i of the illumination radiation 16, _i . E. Of the illumination radiation 16 in the area of the reflecting surface 33 The arrangements of the pupil facet mirrors 20 of the beam path of the intensity distribution and / or the beam path of the illumination radiation 16, in particular the arrangement of the object plane 6, in particular in the illumination optics unit 4, .

In order to adapt the size and / or shape of the reflecting surface 33, the distortion of the grid as a result of the angle of convolution of the pupil facet mirror 20 with respect to the optical axis, in particular the pupil facet mirror 6, Particularly systematic scaling is provided to account for the slope of the substrate 20. Alternatively or additionally, individual spot shapes can take into account the adaptation of the size and / or shape of the reflecting surface 33. This will be described in more detail below.

Generally, the image of the radiation source 2 in the region of intermediate focus is direction-dependent in shape and size. Three-dimensional plasma, in particular, causes an intermediate focus three-dimensional plasma image.

The directional dependence of the plasma image may be due to the anisotropy of the plasma, the imaging characteristics of the collector 17 and the spectral filtering surface structure on the collector 17. As a result, the directional dependence of the plasma image may cause an ellipticity of the illumination spot corresponding to the individual field point. The orientation of the spot can be changed here over the far field. The spot may have any orientation. The lengths of the half-axes are different from each other, and can be in particular in the range of 10% to 40%.

The field facet 25 forms an image of the radiation source 2 at an intermediate focus 18a of a different pupil facet 29. This is illustrated by way of example in FIG.

In the projection of the image of the source 2 of the intermediate focus 18a onto the different pupil facets 29, there is a channel-individual imaging scale.

In addition, due to the different image widths for the different pupil facets 29 which can not be avoided in particular in the case of the switchable field facets 25, defects in the point projection of the image of the source 2 by the field facets 25 imperfection may exist.

Overall, the size, shape and orientation of the illumination spot on the pupil facet mirror 20 is essentially dependent on the field facets 25 assigned to the individual illumination channels. The illumination of the individual pupil facets 29 is the result of, in particular, superimposing the actual spot shapes and the point projections of the field facets 25 individually assigned thereto, from the viewpoints of the field points. This is shown graphically in Fig. The shape of the illumination spot is the result of the envelope of the image of the illumination light partial beam 16 _i ^j .

6, the inclination of the pupil facet mirror 20 with respect to the plane that is parallel to the object plane 6 causes a distortion of the regular grid in which the pupil facets 29 are arranged, Causing system distortion. The tilting of the pupil facet mirror 20 has the effect that the equidistant direction corresponds to the non-equidistant position of the individual pupil facets 29 from the viewpoint of the reticle 7. This can be taken into account by structured scaling of the size and / or shape of the reflecting surface 33 of the pupil facet 29.

The different pupil facets 29 of the pupil facet mirror 20 may have a particularly different shape and / or size. This reference at least relates to a subset of the pupil facets 29. It is of course also possible to form a plurality of subsets or a subset of pupil facets 29 with matching sizes and shapes.

In addition to or as an alternative to structured scaling of the shape and / or size of the reflective surface 33 to account for the inclination of the pupil facet mirror 20, the individual pupil facets 29, particularly the individual pupil facets 29, The size of the pair can be varied individually by pairing the boundaries, i.e. the side edges 32, which are parallel to the other of the adjacent pupil facets 29, are paired and displaced. This is schematically represented by a bi-directional arrow 34 in Figs. 4, 7 and 8.

The shape and / or size of the adjacent pupil facets 29 can be adapted to the actual spot shape and size by this paired individual deformation. In this way, it is possible that the radiation loss due to overexposure of the pupil facet 29 is reduced, in particular minimized, preferably completely avoided. As a result, the transmission of the lighting system 3 is increased. Also, the system stability with respect to drift, in particular, can be improved as a result.

In addition, the illumination spot on the adapted pupil facet 29 can be displaced to further improve the transmission and / or system stability of the illumination system 3. The displacement of the illumination spot on the pupil facet 29 can be achieved by a suitable inclination of the field facet 25. This can be accomplished by a drive mechanism and / or by adjustment of the field facet 25 and / or corresponding operation of its reflective surface.

To determine the exact position of all side edges 32, an optimization algorithm is provided. In this way, the actual intensity distribution of the illumination radiation 16 in the region of the pupil facet mirror 20, particularly in the region of the reflecting surface 33, and / or the array of the pupil facet mirrors 20 of the illumination optical unit 4 In particular, the inclination of the object plane 6 is taken into consideration.

The concept of a paired individual variation of the shape and size of the pupil facet 29 is described below based on the schematic view of Fig. In Figure 7, the two adjacent pupil facets 29 having a light spot (16 _i), each of which is shown by way of illustration. The city light spot _(16-i) is shown here as a region having a certain minimum intensity of illumination radiation (16). The corresponding intensity profile 35 of the illumination radiation 16 in the region of the pupil facet 29 is shown by way of example in the lower portion of Fig. As illustrated by way of example in FIG. 7, overexposure of the pupil facet 29 may be present. Here, a portion of the illumination radiation 16 that is not incident on the correct facet of the pupil facet 29 is not used to illuminate the reticle 7 of the object field 5. Therefore, this becomes the radiation loss 36 identified at the bottom of Fig. 7 by hatching. This radiation loss 36 and in particular the total radiation loss with respect to the two adjacent pupil facets 29 can be reduced, particularly minimized, by the parallel displacement of the adjacent side edge 32 of the reflecting surface 33.

In Figure 7, the position of the side edge 32 ^* before displacement is shown for illustrative purposes. The shape of the pupil facet 29 with the side edges 32 ^* corresponds exactly to the basic shape of the individual pupil facets 29. In the case of the exemplary embodiment shown in Figs. 4, 5 and 7, the hexagon may serve as a basic form for the pupil facet 29 in each case. Other basic forms are likewise possible. The basic form can in particular be selected from a group of various basic forms. This can in particular be selected from a group of up to 5, in particular up to 4, in particular up to 3, in particular up to 2 different basic types. In particular, the basic form can have a maximum of 12, in particular a maximum of 10, in particular a maximum of 8, in particular a maximum of 6, in particular a maximum of 5, in particular a maximum of 4, in particular a maximum of 3. Particularly polygons or generally polygons, that is, circular arc cross-sectional shape edges 32, in particular, take into account the basic form. Equilibrium, especially regular polygons, can serve as a basic form. The basic form is particularly chosen so that the plane can be parquet with it. This can take the form of general parqueting, or in particular in the form of demiregular, semiregular, or square marking.

The actual intensity distribution of the illumination radiation 16 in the region of the pupil facet mirror 20 can be determined by simulation or experimentally. In particular, it can be determined from the data of the radiation source 2 and / or the illumination optical unit 4, in particular calculated.

The angles, in particular the internal angles, between the side edges 32 of the individual pupil facets 29 remain constant as displacements parallel in each case. In the case of a hexagonal pupil facet 29 with an internal angle of 120 degrees, the opposite side edge 32 of the pupil facet 29 remains particularly parallel. However, its length is changed by the parallel displacement. The side edges 32 of the same pupil facet 29 can have different lengths by a factor of up to two. In particular, in the case of a pupil facet 29 having an irregular shape, the side edges 32 of the same pupil facet 29 can also be further detached from each other.

It may be envisaged to define the maximum value at which adjacent pupil facets 29 are allowed to differ in their size. The adjacent pupil facets 29 have a size ratio of at most 1.2, in particular at most 1.1. This can be defined as a boundary condition for the determination of the design of the pupil facet mirror 20. In the preceding description of the exemplary embodiment of the pupil facet mirror 20 based on FIGS. 4-7, it is assumed that the individual pupil facets 29 have a hexagonal reflecting surface 33. This is not entirely necessary. The method according to the invention for adapting the shape and / or size of the reflecting surface 33 can also be used in the case of other facet packings. For example, packing or orthogonal packing with different sized and different types of pupil facets 29 may be provided as a starting packing or starting arrangement of the pupil facet mirror 20. [ Corresponding examples are illustrated by way of example in FIG. In the case of this exemplary embodiment, the basic form of the pupil facet 29 has been selected from two different basic forms. The first subset of pupil facets 29 has a reflecting surface 33 of parallelogram shape. The second subset of pupil facets 29 has a pentagonal reflecting surface 33. In each case, the two parallelogram shaped reflecting surfaces 33 and the two pentagonal reflecting surfaces 33 together have a parallelogram minimum convex envelope. In the case of this embodiment, for the adaptation of the shape and / or size, i.e. for the displacement of the side edge 32, as a boundary condition, such an envelope is in each case two parallelogram shaped reflective surfaces 33, And the two pentagonal reflecting surfaces 33, respectively. In this case, only the side edge 32 that is not in the peripheral region of such an envelope is displaced.

Individual aspects of the method for forming and designing the pupil facet mirror 20 according to the present invention are described below again.

The individual pupil facets 29 are arranged rigidly, i.e., non-displaceable.

The at least two pupil facets 29 are of different sizes by a factor of at least 1.1. The upper limit for the maximum difference in size of the two pupil facets 29 can be defined. The upper limit is for example up to 2, in particular up to 1.5.

The pupil facets 29 may each have a shape developed from a basic shape. The basic form can be selected from the group of up to 5, in particular up to 4, in particular up to 3, in particular up to 2, particularly exactly one basic form in that part. The pupil facet mirror 20 may in other words have up to five pupil facets, in particular up to four, in particular up to three, in particular up to two different types of pupil facets. The pupil facets 29 may all come from the same group. In particular, it is possible to form all the pupil facets 29 into a hexagonal shape.

The design of the pupil facet mirror 20 is based in particular on the regular arrangement of the pupil facets 29. The systematic scaling and / or paired individual deformation of the adjacent reflective surface 33 may be provided to accommodate the size and / or shape of the individual reflective surfaces 33. [

The projection exposure apparatus 1 is provided for producing a microstructured or nano-structured part. With the aid of the projection exposure apparatus 1, at least a part of the reticle 7 is imaged onto the area of the photosensitive layer on the wafer 13. This serves for the lithographic fabrication of microstructured or nanostructured components, in particular semiconductor components, such as microchips. According to the configuration of the projection exposure apparatus 1 as a scanner or a stepper, the reticle 7 and the wafer 13 are moved step by step in the stepper mode in a time synchronized manner in the y direction, . Finally, the photosensitive layer exposed by the illumination radiation 16 on the wafer 13 is developed.

Claims (15)

As the pupil facet mirror 20 for the illumination optical unit 4 of the projection exposure apparatus 1,
A plurality of mirror elements 29 having a polygonal individual reflecting surface 33,
1.2 at least two individual reflecting surfaces (33) with different shapes and / or sizes and
1.3 A pupil facet mirror comprising at least one subset of mirror elements (29) having an irregular shape. The mirror device according to claim 1, wherein the individual reflecting surfaces (33) of the mirror elements (29) have a maximum of five side edges (32) with a maximum of 12 side edges (32) by the parallel displacement of the side edges of at least one of the side edges Characterized in that in each case there is in each case a form developed separately from a basic form selected from a group of different basic types. Method according to claim 1 or 2, characterized in that the shape and / or size of the individual reflecting surfaces (33) are determined by systematic scaling according to the position of the mirror element (29) on the pupil facet mirror (20) and / Characterized in that the pupil facet mirror has paired individual deformations of the reflective surfaces (33). The pupil facet mirror according to any one of claims 1 to 3, wherein at least a part of the individual reflecting surfaces (33) is formed in a hexagonal shape. The pupil facet mirror according to any one of claims 1 to 4, wherein the mirror element (29) is arranged on a lattice point of a regular grid. The pupil facet mirror according to any one of claims 1 to 4, wherein the mirror element (29) is arranged on a grating point of a regular grating which is distorted along one direction. A method for determining the design of the pupil facet mirror (20) according to any one of claims 1 to 6,
7.1 prescribing a basic shape selected from a group of up to five different basic shapes with a maximum of 12 side edges (32) for the shape of the individual reflective surfaces (33);
7.2 adapting the size of the individual reflective surfaces 33 to improve transmission and / or system stability;
7.3 Provided for paired individual transformations and / or structured scaling of adjacent individual reflecting surfaces (33) provided for the adaptation of the size of the individual reflecting surfaces (33). 8. A method according to claim 7, wherein it is envisioned to displace the parallel edges (32) of adjacent mirror elements (29) in pairs for adaptation of the size of the individual reflecting surface (33). The intensity distribution of the illumination radiation (16) in the arrangement of the pupil facet mirror (20) of the illumination optical unit (4) and / or in the area of the individual reflection surface (33) Lt; RTI ID = 0.0 &gt; size). &Lt; / RTI &gt; As the illumination optical unit 4 for the projection exposure apparatus 1,
10.1 A first facet mirror (19) having a plurality of first facets (25) and a second facet mirror
10.2 Illumination optical unit, comprising a second facet mirror in the form of a pupil facet mirror (20) as claimed in any one of claims 1 to 6. 1. An illumination system (3) for a projection exposure apparatus (1)
11.1 Illumination optical unit 4 according to claim 10 and
11.2 An illumination system comprising a source of radiation (2) for generating illumination radiation (16). As an optical system for the projection exposure apparatus 1,
12.1 Illumination optical unit 4 according to claim 10 and
12.2 An optical system comprising a projection optical unit (10) for transferring illumination radiation (16) from an object field (5) to an image field (11). 1. A microphotographic projection exposure apparatus (1) comprising:
13.1 The illuminating optical unit (4), the illuminating optical unit
13.2 projection optical unit 10 for transferring illumination radiation 16 from object field 5 into image field 11 and
13.3 A micro-photographic projection exposure apparatus comprising a source of radiation (2) for generating illumination radiation (16). A method for producing a microstructured or nanostructured part,
14.1) providing the projection exposure apparatus (1) as set forth in claim 13;
14.2) providing a substrate (13) to which a layer of photosensitive material is at least partially applied;
14.3) providing a reticle (7) having a structure to be imaged;
14.4 Projecting at least a portion of the reticle (7) onto the area of the photosensitive layer of the substrate (13) by the projection exposure apparatus (1). A part manufactured by the method according to claim 14.

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