This application claims priority under 35 U.S.C. §119(e)(1) to German Application Serial No. 10 2006 026 032.5, filed on Jun. 1, 2006. The contents of this application is hereby incorporated by reference.
The disclosure relates to EUV illumination systems, as well as related components, systems and methods.
Illumination systems to illuminate a specified illumination field of an object surface with EUV radiation are disclosed in U.S. Pat. No. 6,859,328 B2, US 2005/0093041 A1, U.S. Pat. No. 6,858,853 B2, US 2005/0002090 A1, US 2003/0095623 A1, U.S. Pat. No. 6,400,794 B1 and WO 01/065482 A. A collector to concentrate EUV radiation is disclosed in DE 100 45 265 A1. The illumination systems are part of a projection exposure system, and are used in micro-lithography for producing integrated circuits, to illuminate an object in the form of a mask or reticle.
The disclosure can provide illumination systems and projection exposure systems equipped with them so that either with a given size their EUV throughput is increased, i.e. the reflection losses are reduced, or with a given EUV throughput their size is reduced.
According to the disclosure, this can be achieved, for example, by an illumination system with at least an axis portion of the optical axis being inclined between at least two of the optical elements relative to the illumination main plane.
It has been found that in the case of illumination systems of the abovementioned kind, the following conflicting requirements often should be taken into account: first, the number of components for EUV concentration which are designed to be reflective throughout in the illumination system should be as small as possible, because of the reflection losses. Furthermore, for spatial housing of the EUV source which can be implemented in practice, an optical axis which after the source runs essentially horizontally should be converted via the successive components of the illumination system into an optical axis which runs essentially vertically, to illuminate the object surface. Ideally, a deflection of the optical axis in die region of 90° should be carried out, so that an EUV beam which leaves the EUV source essentially horizontally is deflected into a beam which illuminates the illumination field essentially vertically, e.g. at an angle of 6° to the normal onto the illumination field. Finally, to minimise the reflection losses, the angle of incidence on the reflecting components of the illumination system, i.e. on the reflecting optical elements after the collector and preferably on the EUV collector itself, should either be very large, i.e. in the region of grazing incidence, or very small, i.e. in the region of vertical incidence. The illumination system according to the disclosure fulfills these requirements. Preferably, the optical axis meets the reflecting optical elements which are arranged successive to the collector at an angle of incidence which is either greater than 70° or less than 20°.
According to the disclosure, the result is an illumination system which on the one hand supplies a high EUV throughput, because the number of reflections is minimised, and simultaneously reflections with favourable angles of reflection take place, and also makes compact construction possible, because a relatively large angle of deflection for the optical axis is implemented. Even an angle of deflection which is only slightly greater than 30° makes possible an illumination system with an overall height which does not make excessive demands on a factory for integrated circuits. In particular, even in the case of spatially extended sources, illumination systems in which the source is arranged not more than 2.5 m below the object surface in the vertical direction can be implemented. The illumination system can therefore be used in typical clean rooms.
A first variant of an illumination system according to the disclosure uses an optical axis which is folded in three optical directions, at least a portion of the optical axis being inclined relative to the rest of the optical axis. This allows a particularly compact arrangement of the optical elements of the illumination system, without an obstruction being caused by these optical elements. These advantages prevail a possibly higher effort regarding optical or mechanical design, since as a rule there is no plane of mirror symmetry of the system arrangement regarding a folded system.
A size of the illumination field of at least 100 mm2 permits a high object throughput. The direct result of this is faster production of integrated circuits.
An illumination system wherein the second optical element is part of an optical device which includes further optical elements, and which guides the EUV radiation reflected by the first optical element along the optical axis, and images the first optical element into the illumination field being arranged in the image plane, which coincides with the object surface, permits precise imaging of the first optical element into the image plane.
Versions of the illumination system wherein (1) the optical device includes at least two further optical elements after the second optical element, i.e. a third and a fourth optical element and an axis portion of the optical axis being inclined between the third and the fourth element of the optical device relative to the illumination main plane, wherein (2) the optical device includes at least two further optical elements after the second optical element, i.e. a third and a fourth optical element and an axis portion of the optical axis being inclined between the or a first and the or a second optical element relative to the illumination main plane and wherein (3) an axis portion between the second and the third element of the optical device is inclined relative to the illumination main plane, consistently extend the partial concept according to the disclosure of folding the optical axis in the three spatial directions. Because of the differently folded portions of the optical axis, compact arrangements of the optical elements of the illumination system can be implemented.
An illumination system wherein after the second optical element, a maximum of two further optical elements are provided, an axis portion of the optical axis between the collector and the first optical element being inclined relative to the illumination main plane, the source of the EUV radiation being a plasma source, permits irradiation of EUV radiation, which can hardly be obstructed by downstream optical elements of the illumination system, from the collector. An optical device having an axis portion between the first and die second optical element which is inclined relative to the illumination main plane, has particularly few optical elements, and can therefore be designed particularly efficiently in the EUV throughput. An EUV collector which concentrates the EUV radiation through exactly one reflection is known in various versions from US 2005/0002090 A1 and US 2005/0093041 A1. An EUV collector with which the EUV radiation is concentrated through two reflections is known from US 2003/0095623 A1.
The versions of the illumination system wherein (1) an axis portion of the optical axis between the first and the second optical element is inclined relative to the illumination main plane and wherein (2) the optical device, in addition to the second optical element, includes precisely two further optical elements, i.e. a third optical element and a further optical element, and wherein an axis portion of the optical axis between the collector and the first optical element and an axis portion of the optical axis between the second optical element and the third optical element being inclined relative to the illumination main plane, also extend the concept of folding in the three spatial directions, so that compact arrangements result, in particular with a high angle of deflection of the optical axis.
A second variant of an illumination system according to the disclosure, wherein the optical device, in addition to the second optical element, includes precisely three further optical elements, i.e. a third optical element, a fourth optical element and a fifth optical element, the optical axis meeting the third, fourth and fifth optical elements at an angle of incidence which is greater than 60°, in particular greater than 70°, allows a high angle of deflection of the optical axis even if no folding of the optical axis in the three spatial directions is used. By distributing the deflection of the optical axis to multiple optical elements, which are operated with grazing incidence, the optical axis can be efficiently deflected, without the optical elements obstructing each other. In particular, the second optical element, which can be implemented, in particular, as a pupil facet element, can be operated efficiently in grazing incidence. The second optical element can then be implemented so that a relatively large area of it is acted on in reflection, which reduces the thermal load on the second optical element. Preferably, the optical axis meets in this second variant the third, fourth and fifth optical elements at an angle of incidence which is greater than 70°.
Numerical apertures of the illumination of at least 0.02, preferably at least 0.03 and illumination field sizes of at least 500 mm2, preferably at least 800 mm2 ensure effective illumination of the object.
As far as the projection exposure system is concerned, tie initially stated object is achieved by a projection exposure system having an illumination system according to the disclosure.
The advantages of this projection exposure system, of the method of microlithographic production of microstructured components, having the following steps:
and the advantages of the components being produced according to is method correspond to those which were stated above with reference to the illumination system.
Embodiments of the disclosure are described in more detail below with reference to the drawings.
At top right in
As the source 8 of the EUV radiation 5, a plasma source is used. Other source types for EUV radiation are also possible.
A collector 9 concentrates the EUV radiation 5, which the source 8 emits, by reflection in the direction of the optical axis 7. Along the optical axis 7, the EUV radiation 5 is guided by successive optical elements, which will be described. As in the case of the collector 9, these optical elements are the optical elements which reflect the EUV radiation 5.
After the collector 9, a first optical element 10 is used to generate secondary light sources in the illumination system 1. The first optical element 10 is also called a field raster element.
In the beam path after the first optical element 10, at the location of the secondary light sources which the first optical element 10 generates, a second optical element 11 is arranged. This optical element is also called a pupil raster element, and is in the area of a pupil plane of the illumination system 1. Representing the many secondary light sources which the first optical element 10 generates, in
The optical device 12 includes, after the second optical element 11, a third optical element 13, a fourth optical element 14 and a fifth optical element 15.
The secondary light sources 11a are imaged by the optical elements 13 to 15, and by the reflection on the object surface 3, into a pupil plane 16 of the schematically indicated projection optical system 16a. From the entry into the projection optical system 16a, the real course of the beams deviates from the course which is drawn in
Between the last optical element of the optical device 12, i.e. the fifth optical element 15, and the illumination field 2, runs a portion 17 of the optical axis 7, called the field axis portion below. The field axis portion 17 of the optical axis lies in an illumination main plane 18, which in the case of the illumination system 1 according to
Between the collector 9 and the first optical element 10, a portion 19 of the optical axis 7, also called the source axis portion below, is arranged. The source axis portion 19 also lies in the illumination main plane 18. In the case of the known illumination system 1 according to
Embodiments according to the disclosure of illumination systems are described below on the basis of the very schematic
In the case of the illumination system 1 according to
In the case of the version according to
An axis portion 20 of the optical axis between the third optical element 13 and the fourth optical element 14 is inclined to the illumination main plane 18, which is indicated in
In the case of the version according to
In the case of the illumination system 1 according to
The optical axis 7 meets the optical elements 10, 11, 13 and 14 at an angle of incidence which is less than 20°. The optical axis 7 meets the fifth optical element 15 at an angle of incidence which is greater than 70°. The projection of the source axis portion 19 onto the illumination main plane 18, with the projection of the field axis portion 17 onto the illumination main plane 18, encloses an angle of about 55°.
In the case of the version of the illumination system 1 according to
In particular, the result is that the fifth optical element 15 is also arranged relative to the third optical element 13 displaced in the positive x direction. The optical elements 10, 13, 15 can therefore, as shown in
The angle of incidence below which the optical axis 7 falls on the optical elements 10, 11, 13 and 14 is less than 20°. The angle of incidence below which the optical axis 7 falls on the fifth optical element 15 is greater than 70°. The angle which a projection of the source axis portion 19 onto the illumination main plane 18 encloses with a projection of the field axis portion 17 onto the illumination main plane 18 is about 70°.
In the case of the illumination system 1 according to
In the case of the illumination system 1 according to
The optical axis 7 meets the first optical element 10 at an angle of incidence which is less than 20°. The optical axis 7 meets the optical elements 11 and 15 at an angle of incidence which is greater than 70°.
In the case of the illumination system 1 according to
In the case of the version according to
Like the version according to
In the case of the version according to
The source axis portion 19 is inclined relative to the illumination main plane 18, which in the case of the version according to
The optical axis 7 meets the optical elements 10 and 11 at an angle of incidence which is less than 20°. In the case of the version according to
In the case of the illumination system 1 according to
As in the case of the version according to
In the case of the version according to
The source axis portion 19 is inclined relative to the illumination main plane 18, which in the case of the version according to
The optical axis 7 meets the optical elements 10, 11 and 13 at an angle of incidence which is less than 20°. The optical axis 7 meets the fifth optical element 15 at an angle of incidence which is greater than 70°.
In the case of the illumination system 1 according to
Like the versions according to
In the case of the version according to
The version according to
The optical axis 7 meets the optical elements 10 and 11 at an angle of incidence which is less than 20°.
In the case of the illumination system 1 according to
Modifications of the other versions according to
Combinations of the x displacement in the positive or negative direction other than those described above in relation to the versions according to the disclosure are also possible.
Similarly to the illumination system 1 according to
The following table clarifies the positions of the optical elements 10, 11, 13, 14, 15 in the xyz co-ordinates according to
The following table gives the angle of incidence of the optical axis 7 onto the optical elements 10, 11, 13, 14, 15:
The following table shows the angles of the projections of the axis portions 19, 21, 22, 20, 23 and 17 to the xz and yz planes. The second column gives the angle of the projection of the axis portions onto the yz plane to the xz plane, and the third column gives the angle of the projection of the axis portions onto the xz plane to the yz plane.
The angles of the second column of the above table can be read directly from
In column 2 of the above table, it can be seen directly that the angle between a projection of the source axis portion 19 onto the illumination main plane 18 and a projection of the field axis portion 17 onto the illumination main plane is 51°.
Below is another table, giving the orientation of the optical elements 10, 11, 13, 14 and 15. For this purpose, for each of the optical elements 10, 11, 13, 14 and 15, a local element co-ordinate system, the origin of which is defined by the intersection of the optical axis 7 with the mirror surface, is defined. The normal vector points to the mirror surface in the z′ direction of the local element co-ordinate system. The element co-ordinate systems x′, y′, z′ are obtained from the xyz co-ordinate system by rotation first by an angle a around the x axis and then by an angle b around the new y′ axis. Since it is assumed for simplicity that the optical elements 10, 11, 13, 14, 15 are spherical mirrors, a rotation of the element co-ordinate system x′, y′, z′ around the z axis is irrelevant. The following angles of rotation convert the stationary x, y, z co-ordinate system into the appropriate element co-ordinate system:
In the case of all versions according to the disclosure, i.e. according to
The illumination device 1 according to the versions presented above is used to produce microstructured components on the wafer as follows: first the wafer, onto which a layer of a light-sensitive material is applied at least in certain regions, is provided. The object 4, with a mask which shows the structures to be imaged, is also provided. Then, using the projection illumination system, at least a portion of the object 4 is projected onto a portion of the light-sensitive layer on the wafer.
Number | Date | Country | Kind |
---|---|---|---|
10 2006 026 032 | Jun 2006 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
6400794 | Schultz et al. | Jun 2002 | B1 |
6858853 | Antoni et al. | Feb 2005 | B2 |
6859328 | Schultz et al. | Feb 2005 | B2 |
7109497 | Antoni et al. | Sep 2006 | B2 |
7142285 | Antoni et al. | Nov 2006 | B2 |
7186983 | Mann et al. | Mar 2007 | B2 |
20030095623 | Singer et al. | May 2003 | A1 |
20050002090 | Singer et al. | Jan 2005 | A1 |
20050093041 | Singer et al. | May 2005 | A1 |
Number | Date | Country |
---|---|---|
100 45 265 | Mar 2002 | DE |
WO 0165482 | Sep 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20070295919 A1 | Dec 2007 | US |