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Title:
DEVICE FOR CLEANING A SURFACE IN THE INTERIOR OF AN OPTICAL SYSTEM
Document Type and Number:
WIPO Patent Application WO/2021/048197
Kind Code:
A1
Abstract:
The present invention relates to a device for cleaning a surface (302, 402) in the interior of an optical system (300, 400), in particular of an EUV lithography system, comprising a rod-shaped element (303, 403), wherein the rod-shaped element comprises a visualization unit (304, 404) configured to visualize contaminates (320, 420) on the surface, and a cleaning unit (305, 405) configured to remove contaminates from the surface, and a distance sensor (306, 406), wherein the distance sensor is configured in such a way as to measure the distance between the surface and the end of the rod-shaped element, and a connection element (307, 407) configured in such a way that it can be secured at an opening (211, 311, 411) of the optical system, and wherein the connection element comprises a guide element (308, 408), with the aid of which the rod-shaped element (303, 403) can be guided. The invention further relates to the use of the device for cleaning a surface in the interior of an optical system, and to a method for cleaning in the interior of an optical system, in particular of a lithography system.

Inventors:
DIESCH JOVANA-MARIA (DE)
SIGEL BENJAMIN (DE)
PETASCH THOMAS (DE)
Application Number:
PCT/EP2020/075182
Publication Date:
March 18, 2021
Filing Date:
September 09, 2020
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
ZEISS CARL SMT GMBH (DE)
International Classes:
G03F7/20
Domestic Patent References:
WO2015043833A12015-04-02
WO2016142370A12016-09-15
WO2009036168A22009-03-19
Foreign References:
US20170357162A12017-12-14
DE19830438A12000-01-13
Attorney, Agent or Firm:
OKON, Thomas (DE)
Download PDF:
Claims:
Patent Claims

1. Device for cleaning a surface (302, 402) in the interior of an optical system (300, 400), in particular of an EUV lithography system, comprising a rod-shaped element (303, 403), wherein the rod-shaped element comprises a visualization unit (304, 404) configured to visualize contaminates (320,

420) on the surface, and a cleaning unit (305, 405) configured to remove contaminates from the surface, and a distance sensor (306, 406), wherein the distance sensor is configured in such a way as to measure the distance between the surface and the end of the rod-shaped element, and a connection element (307, 407) configured in such a way that it can be secured at an opening (211 , 311 , 411 ) of the optical system, and wherein the connection element comprises a guide element (308, 408), with the aid of which the rod shaped element (303, 403) can be guided.

2. Device according to Claim 1, characterized in that the guide element (308, 408) is equipped with a ball-and-socket joint.

3. Device according to Claim 1 or 2, characterized in that the guide element (308, 408) further comprises a securing unit (309, 409) for securing the rod-shaped element (303, 403).

4. Device according to Claim 3, characterized in that the guide element (308, 408) further comprises a displacement unit (310, 410) for the fine positioning of the rod-shaped element (304, 404).

5. Device according to Claim 4, characterized in that the displacement unit (310,

410) for fine positioning is operated by way of a manual crank or an actuator.

6. Device according to any of the preceding claims, characterized in that the visualization unit (304, 404) and the cleaning unit (305, 405) are arranged in direct proximity to one another.

7. Device according to Claim 6, characterized in that the rod-shaped element (303, 403) is enclosed by a tube, and wherein the distance sensor (306, 406) is integrated into the tube.

8. Device according to any of the preceding claims, further comprising an anti collision protection means (325), in particular plastic lamellae, which is fitted at the end of the rod-shaped element (303, 403).

9. Device according to any of the preceding claims, wherein the visualization unit (304) is a (video)endoscope, a horoscope, a camera, or a detector.

10. Device according to any of the preceding claims, further comprising an illumination unit (417) designed in such a way that it illuminates the surface section visualized by the visualization unit (404).

11. Device according to any of the preceding claims, further comprising a shield (416), which is fitted to the rod-shaped element (403) in such a way that it can be folded out after insertion into the optical system and is configured such that it blocks extraneous light, in particular from other surfaces, in the folded-out state.

12. Device according to any of the preceding claims, wherein the cleaning unit (305, 405) comprises a suction extractor and/or a means for detaching the contaminates from the surface (302, 402).

13. Device according to any of Claims 1 - 11, wherein the cleaning unit (305, 405) comprises a surface measuring probe.

14. Device according to any of the preceding claims, further comprising a means for sampling (418), in particular Kalrez material, a PMC tape or a clean tip, said means being fitted at the end of the rod-shaped element (403).

15. Device according to any of the preceding claims, characterized in that the distance sensor (306, 406) is a capacitive or ultrasonic sensor.

16. Device according to any of the preceding claims, characterized in that the distance sensor (306, 406) outputs acoustic or optical signals, wherein the signals are such that conclusions about the distance between the surface and the end of the rod-shaped element can be drawn therefrom.

17. Use of the device according to any of the preceding claims for cleaning a surface (302, 402) in the interior of an optical system (300, 400), in particular of an EUV lithography system. 18. Method for cleaning a surface (302, 402) in the interior of an optical system (300,

400), comprising the steps of securing a connection element (307, 407) at an opening (311 , 411 ) of the optical system, wherein the connection element is adapted to the outer geometry of the optical system and wherein the connection element comprises a guide element (308, 408), inserting a rod-shaped element (303, 403), which comprises a visualization unit

(304, 404), a cleaning unit (305, 405) and a distance sensor (306, 406), through the guide element (308, 408) into the interior of the optical system, using the visualization unit (304, 404) for visualizing the contaminate, moving the rod-shaped element (303, 403) to a suitable distance from the surface on the basis of the distance signal of the distance sensor (306, 406), and subsequent cleaning with the aid of the cleaning unit (305, 405).

Description:
Device for cleaning a surface in the interior of an optical system

The invention relates to a device for cleaning a surface in the interior of an optical system, in particular of a lithography system, to a use of the device for cleaning a surface in the interior of an optical system, and to a method for cleaning a surface in the interior of an optical system.

Lithography is used for production of semiconductor components, such as for example integrated circuits or LCDs. The lithography process is conducted in what is called a projection exposure apparatus, which comprises an illumination system and a projection lens. The image of a mask (reticle) illuminated by means of the illumination system is projected here by means of the projection lens onto a substrate (e.g. a silicon wafer) coated with a light-sensitive layer (photoresist) and disposed in the image plane of the projection lens, in order to transfer the mask structure to the light-sensitive coating of the substrate.

For the purposes of this application, a lithography system is understood as meaning an optical system that can be used in the field of lithography. Besides the projection exposure apparatus described above, which consists of the optical subsystems of illumination system and projection lens mentioned above and which serves for producing semiconductor components, the optical system can also be an inspection system for inspecting a mask (also called reticle hereinafter) used in a lithography system, or for inspecting a semiconductor substrate (also called wafer hereinafter) to be structured, or a metrology system used for measuring a lithography system or parts thereof, for example for measuring a projection lens.

At the present time, light or radiation in the deep ultraviolet (DUV: deep ultraviolet, VUV: very deep ultraviolet) or in the far, extreme ultraviolet spectral range (EUV: extreme ultraviolet) is used, particularly, in lithography systems. Customary light wavelengths for DUV or VUV systems are currently between 248 nm and 193 nm. In order to achieve even higher lithographic resolutions, radiation ranging to soft X-ray radiation (EUV: extreme ultraviolet) or quasi hard X-ray radiation (XEUV: X-Ray EUV) having a wavelength of a few nanometres is used. In corresponding projection exposure apparatuses, this makes it possible to image extremely small structures onto wafers with a very high resolution. In lithography systems designed for the EUV range, owing to the lack of availability of suitable light-transmissive refractive materials, mirrors are used as optical components for the imaging process.

In such systems, contaminates, for example resulting from particles, can lead to losses in performance, considerable damage or even to the complete failure of the entire apparatus. Therefore, diverse, in some instances very laborious, methods for cleaning the individual components and/or for avoiding contaminates, in particular particle contaminates, are used in the production process.

It is nevertheless inevitable that (particle) contaminates will be present at the end of the production process after all the individual components or the modules composed of individual components have been assembled to form the overall system, and so it is then necessary to carry out cleaning of a surface in the interior of the optical system. Contamination of surfaces in the interior of the optical system can occur during operation of the lithography systems as well.

The surfaces situated in the interior of the optical system are then generally difficult to access in the overall system. Access is afforded for example by openings in the optical system for the radiation to enter or exit or, in the case of optical systems constructed from exchangeable individual modules, by the openings produced after a module has been demounted. Moreover, primarily if the surface is an optical surface, for example the surface of a lens element or of a mirror, particular caution must be exercised since the surfaces can easily be damaged by being touched. Therefore, even for experts, cleaning that is usually carried out manually presents a great challenge and a great risk of damage and failure.

It is therefore an object of the invention to provide a device for cleaning a surface in the interior of an optical system, a use of such a device for cleaning a surface in the interior of an optical system, and a method for cleaning a surface in the interior of an optical system which enable as effective, rapid and reliable cleaning as possible with the least possible risk of damage and failure.

This is achieved by means of a device for cleaning a surface in the interior of an optical system, in particular of an EUV lithography system, comprising a rod-shaped element, wherein the rod-shaped element comprises a visualization unit configured to visualize contaminates on the surface, and a cleaning unit configured to remove contaminates from the surface, and a distance sensor, wherein the distance sensor is configured in such a way as to measure the distance between the surface and the end of the rod-shaped element, and a connection element configured in such a way that it can be secured at an opening of the optical system, and wherein the connection element comprises a guide element, with the aid of which the rod-shaped element can be guided.

The regions of the contaminated surface which are situated in the interior of the optical system can be reached by the rod-shaped element when the rod-shaped element is inserted into the optical system through an opening initially usually manually.

In order to clean the surface of contaminates, in particular particles, fibres or fluff, these firstly have to be visualized on a predefined surface section by a visualization unit and then be removed from the surface with the aid of the cleaning unit. In this case, the visualization unit serves firstly for finding and for visualizing the contaminates. The contaminates found can then be assessed and, if necessary, removed from the surface by the cleaning unit. Secondly, after cleaning by the cleaning unit, the visualization unit can also be used to verify the cleaning result.

In order to minimize the risk of damage and failure, as well as for effective cleaning of the surfaces, it is furthermore necessary for a distance sensor to be integrated into the device, which distance sensor measures the distance between the surface and the end of the rod-shaped element. On the one hand, the surface must not be touched, in order to avoid damage to the surface or positional displacements. On the other hand, for effective cleaning, the distance between the surface and the end of the rod-shaped element must be less than a maximum distance in order that the cleaning unit functions optimally. Preferably, care must be taken here to ensure that the distance sensor functions in all spatial directions, and not just in a direction parallel to the rod-shaped element. For this purpose, it is necessary to integrate the distance sensor into the device for cleaning such that shading by the other elements, in particular by the cleaning unit and the visualization unit, does not occur.

The interplay of the connection element, which is adapted to the outer geometry of the optical system and can be secured there, and the guide element facilitates the usually manual insertion of the rod-shaped element. In this case, with guidance of the rod shaped element, a controlled movement of the rod-shaped element from the opening of the optical system toward the surface to be cleaned (translation) and also a rotary movement about the pivot of the guide element (rotation) are made possible. Thus the entire surface in the interior can ideally be reached.

In one preferred embodiment, the guide element can comprise a ball-and-socket joint, which allows a rotary movement about the pivot in addition to translation into the interior of the system. By means of the ball-and-socket joint, the rod-shaped element is mounted rotatably about the pivot of the ball-and-socket joint and, given sufficient structural space, can be displaced arbitrarily at both solid angles.

In one preferred embodiment, the guide element further comprises a securing unit for securing the rod-shaped element. If the end of the rod-shaped element is situated for example at a location of the surface at which a contaminate was visualized by the visualization unit and if there is a suitable distance with respect to the surface, the rod shaped element can be secured and then the cleaning can be carried out without the risk of failure. Preferably, for this purpose, the rod-shaped element can be clamped with the aid of a screw, for example. The generation of further particles should be avoided or minimized in this case. As an alternative to screwing, clamping by means of an eccentric would also be conceivable. Moreover, it is possible, conversely, to clamp the rod-shaped element in the non-actuated state and to make it movable by the introduction of force and the associated release of the clamping.

In one preferred embodiment, the rod-shaped element also comprises a kinematic system for angled bending, whereby optical units that are not accessible rectilinearly can be made reachable. Said kinematic system can be simple joints that can be actuated in their degree of freedom.

If the connection element furthermore comprises a displacement unit for fine positioning, the position of the rod-shaped element relative to the surface to be cleaned can be further controlled and optimized by actuation of the displacement unit. It is then possible, for example, after manual coarse positioning, firstly to fix the rod-shaped element. Subsequently, with the aid of the displacement unit, it is possible to move to the optimum position with regard to the exact location of the contaminate and the optimum distance with respect to the surface with the aid of the visualization unit and the distance sensor. As a result, it is possible to carry out effective cleaning with a low risk of failure. In one preferred embodiment, the displacement unit for fine positioning is operated by way of a (manual) crank or a controllable actuator. Diverse actuators that can be used to implement a translational movement are conceivable for this. For example including actuators that operate according to the piezo-crawler principle or else hydraulically or pneumatically/hydraulically/electrically operated linear drives.

In one preferred embodiment, the visualization unit and the cleaning unit are arranged in direct proximity to one another in order to enable as compact a design as possible. This not only facilitates the insertion and positioning in the interior of the optical system, but primarily has the effect that if a contaminate, in particular a particle, fluff or a fibre, was able to be visualized with the aid of the visualization unit, said contaminate can be removed directly with the aid of the cleaning unit arranged in direct proximity, without once again displacing the device for cleaning. If the distance between visualization unit and cleaning unit is too large, either the cleaning performance of the cleaning unit is impaired or the cleaning unit has to be displaced once again before cleaning, which entails the risk that the contaminate cannot be removed optimally because it has not been found optimally.

Furthermore, in one preferred embodiment, the rod-shaped element can be enclosed by a tube and the distance sensor can be integrated into the tube in order to enable an even more compact design. In the case of the location of the distance sensor, care should be taken to ensure that the latter functions in all spatial directions, and not just in a direction parallel to the rod-shaped element. In particular, shading into a spatial region by the other elements must be excluded.

In one preferred embodiment, the rod-shaped element further comprises an anti collision protection means which is fitted at the end of the rod-shaped element. Said means can be, in particular, plastic lamellae, PMC tape or Kalrez material. If a surface, specifically an optical surface, were indeed touched, it would be better protected by the anti-collision protection means and the risk of damage or failure would thus additionally be minimized.

In one preferred embodiment, the visualization unit is a (video)endoscope, a boroscope, a camera, or a detector. All these means are suitable for visualizing contaminates on the surface and for transmitting the signal towards the outside to an image generator, such as a screen, for example. In one preferred embodiment, the device for cleaning can further comprise an illumination unit designed in such a way that it illuminates the surface section visualized by the visualization unit. This can involve for example a ring electrode or an LED ring, wherein the LED ring is switchable as far as possible sequentially. An improved illumination of the contaminates to be visualized by means of grazing light can thus be achieved. Since the surface to be cleaned is a surface in the interior of the optical system, the lighting conditions are not ideal and can be improved by such an illumination unit, whereby the cleaning result can be improved.

In this case, the illumination unit can also be integrated directly in the visualization unit.

In one preferred embodiment, an illumination with different spectra can be effected in this case. In this regard, it is possible to use an illumination with UV light, for example, in which organic contamination can be particularly lit up and identified more easily.

Likewise, an indirect illumination can also lead to a good visualization of the contamination.

In one preferred embodiment, the visualization can be effected by means of a scattered light method. For this purpose, the light, for example laser light, generated by the illumination unit is shone onto the predefined surface section and the scattered light generated is detected, for example by a suitably positioned camera or a detector. As a result of the detection of the scattered light, the resolution can be improved and for example smaller particles can thus be visualized.

In one preferred embodiment, the device for cleaning can further comprise a shield, which is fitted to the rod-shaped element in such a way that it can be folded out after insertion into the optical system and is configured such that it blocks extraneous light, in particular back-reflections from other surfaces, in the folded-out state. Blocking the extraneous light has the effect that only light and thus information passes from the surface section to be visualized into the visualization unit and disturbing superimpositions can be blocked and the visualization and subsequently the cleaning can thus be improved.

In one preferred embodiment, the cleaning unit comprises a suction extractor and/or a means for detaching the contaminates from the surface. In this case, the suction extractor is able to extract the contaminates, particularly if they are particles, fluff or fibres, by suction from the surface. The detaching means can be, for example, a compressed air probe or a CO2 jet unit, which can detach contaminates from the surface with the aid of C02-pellets or CO2 snow.

Depending on the location or type of the surface in the optical system, it may be sufficient only to detach the contaminate from the surface. With the combination of a suction extractor and a detaching means, however, the contaminates can firstly be detached and then be extracted by suction and thus be completely removed from the optical system.

Furthermore, the cleaning unit can also be a surface measuring probe. The latter can detach contaminates using compressed air and then extract them by suction. The extracted gas is subsequently fed to an analysis unit, for example an RGA (residual gas analysis) unit. The exact constitution of the contaminate can thus be examined.

In a further preferred embodiment, the device for cleaning further comprises a means for sampling, in particular Kalrez material, a PMC tape or a clean tip, said means being fitted at the end of the rod-shaped element. The contaminates would thus be able to be removed from the optical system and then be able to be viewed and analysed using suitable means, such as, for example, a scanning electron microscope (SEM) or other means for sample analysis. Knowledge of the material, under certain circumstances, allows the cause of the contamination to be deduced and then remedied.

In one preferred embodiment, the distance sensor is a capacitive or ultrasonic sensor.

In one preferred embodiment, the distance sensor outputs acoustic or optical signals, wherein the signals are such that conclusions about the distance between the surface and the end of the rod-shaped element can be drawn therefrom. This can involve an acoustic signal that varies for example the pitch or the frequency of the signal as the surface is approached more closely, in order to warn the user. It is likewise conceivable for an optical signal to be output instead of or in support of said acoustic signal.

Furthermore, the device for cleaning can comprise a control unit. With accurate knowledge of the geometry and location of the surface, it is possible to move precisely to the surface in the interior of the optical system with the aid of the control unit and the displacement unit. Automated cleaning of the surface is thus made possible.

In this case, the signal of the distance sensor can also be used as an input for the control unit. In this regard, the device for cleaning can also move to the surface in an automated manner with the aid of the displacement unit controlled by the control signal, and efficient and low-risk cleaning can thus be made possible.

Furthermore, the invention relates to the use of the device according to any of the preceding embodiments for cleaning a surface in the interior of an optical system, in particular of an EUV lithography system.

Furthermore, the invention relates to a method for cleaning a surface in the interior of an optical system, comprising the steps of securing a connection element at an opening of the optical system, wherein the connection element is adapted to the outer geometry of the optical system and wherein the connection element comprises a guide element (308, 408), inserting a rod-shaped element, which comprises a visualization unit, a cleaning unit and a distance sensor, through the guide into the interior of the optical system, using the visualization unit for visualizing the contaminate, moving the rod-shaped element to a suitable distance from the surface on the basis of the distance signal, and subsequent cleaning with the aid of the cleaning unit.

Further advantageous configurations and aspects of the invention are the subject matter of the exemplary embodiments of the invention described below. In the text that follows, the invention is explained in more detail on the basis of preferred embodiments and with reference to the accompanying figures.

In the figures:

Fig. 1 shows a basic schematic diagram concerning the construction of a DUV lithography apparatus

Fig. 2 shows a basic schematic diagram concerning the construction of an EUV lithography apparatus

Fig. 3 shows a schematic illustration of a device for cleaning in accordance with a first embodiment of the invention, said device being attached to a lithography system

Fig. 4 shows a schematic illustration of a device for cleaning in accordance with a second embodiment of the invention, said device being attached to a lithography system Fig. 1 illustrates an exemplary DUV projection exposure apparatus 100. The projection exposure apparatus 100 comprises an illumination system 103, a device known as a reticle stage 104 for receiving and exactly positioning a reticle 105, by which the later structures on a wafer 102 are determined, a wafer holding 106 for holding, moving and exactly positioning the wafer 102 and an imaging facility, to be specific a projection lens 107, with multiple optical elements 108, which are held by way of mounts 109 in a lens housing 140 of the projection lens 107.

The optical elements 108 may be designed as individual refractive, diffractive and/or reflective optical elements 108, such as for example lens elements, mirrors, prisms, terminating plates and the like.

The basic functional principle of the projection exposure apparatus 100 makes provision for the structures introduced into the reticle 105 to be imaged onto the wafer 102.

The illumination system 103 provides a projection beam 111 in the form of electromagnetic radiation, which is required for the imaging of the reticle 105 on the wafer 102. A laser, plasma source or the like may be used as the source of this radiation. The radiation is shaped in the illumination system 103 by means of optical elements such that the projection beam 111 has the desired properties with regard to diameter, polarisation, shape of the wavefront and the like when it is incident on the reticle 105. An image of the reticle 105 is generated by means of the projection beam 111 and transferred from the projection lens 107 onto the wafer 102 in an appropriately reduced form. In this case, the reticle 105 and the wafer 102 may be moved synchronously, so that regions of the reticle 105 are imaged onto corresponding regions of the wafer 102 virtually continuously during a so-called scanning operation. For the entrance and exit of the radiation and also at the transition between the individual subsystems, for example from the illumination system 103 into the projection optical unit 107, openings (not shown in the figure) can be present. Said openings can be used as access to the surfaces in the interior of the optical system. In addition, the optical system can be constructed from individual submodules, which can be demounted individually from the optical system for better maintenance. Consequently, further openings (not shown in the figure) arise in the event of maintenance and can be used as access to the surfaces. Fig. 2 shows by way of example the basic construction of an EUV lithography system 200 for which the invention can find application. An illumination system 201 of the lithography system 200 comprises, besides a radiation source 202, an optical unit 203 for the illumination of an object field 204 in an object plane 205. A reticle 206 arranged in the object field 204 is illuminated, said reticle being held by a reticle holder 207, illustrated schematically. The radiation source 202 can emit EUV radiation 213, in particular in the range of between 5 nanometres and 30 nanometres. Optically differently configured and mechanically adjustable optical elements 215 to 220 are used for controlling the radiation path of the EUV radiation 213. In the case of the EUV projection exposure apparatus 200 illustrated in Fig. 2, the optical elements are configured as adjustable mirrors in suitable embodiments, which are mentioned merely by way of example below.

The EUV radiation 213 generated by means of the radiation source 202 is aligned by means of a collector integrated in the radiation source 202 in such a way that the EUV radiation 213 passes through an intermediate focus in the region of an intermediate focal plane 214 before the EUV radiation 213 impinges on a field facet mirror 215. Downstream of the field facet mirror 215, the EUV radiation 213 is reflected by a pupil facet mirror 216. With the aid of the pupil facet mirror 216 and an optical assembly 217 having mirrors 218, 219, 220, field facets of the field facet mirror 215 are imaged into the object field 204.

The projection optical unit 208 serves for imaging the object field 204 into an image field 209 in an image plane 210. A structure on the reticle 206 is imaged on a light-sensitive layer of a wafer W arranged in the region of the image field 209 in the image plane 210, said wafer being held by a wafer holder 212 that is likewise illustrated in part. By way of example, the optical elements 221 to 224 are used for this purpose.

For the entrance and exit of the radiation and also at the transition between the individual subsystems, for example from the illumination system 201 into the projection lens 208, openings (211 ) can be present. Said openings can be used as access to the surfaces in the interior. In addition, the optical system can be constructed from individual submodules, which can be demounted individually from the optical system for better maintenance. Consequently, further openings (not shown in the figure) arise in the event of maintenance and can be used as access to the surfaces.

Fig. 3 shows a schematic illustration of a device for cleaning in accordance with a first embodiment of the invention, said device being attached to a lithography system. In this case, for the sake of clarity, the optical system (300) is shown only by a housing (312) having an opening (311) and an optical element (301) having a surface (302) to be cleaned, said optical element being situated in the interior. Here in the case of a lithography system, the surface of the optical elements is usually equipped either with a highly reflective layer system in the case of mirrors, or with an antireflection layer system in the case of a refractive optical element, such as a lens element, for example. The layer systems usually consist of complex sequences of many individual layers of different materials. In the case of these layer systems, even small defects or contaminates thereon can have an adverse effect on the performance of the optical system. The surface (302) to be cleaned can also be a housing wall situated in the interior or an arbitrary surface of structural or mechanical components, for example. Even if these surfaces are typically not damaged as easily or the contamination thereof does not directly affect the performance of the optical system, particles, fluff or fibres, for example, must also be removed from there, if only so that they do not spread from there to other surfaces, for example optical surfaces.

In this case, in the present exemplary embodiment, the device for cleaning a surface (302) in the interior of an optical system (300) comprises a rod-shaped element (303), in which the visualization unit (304) and the cleaning unit (305) are arranged in direct proximity to one another, in order to enable as compact as a design as possible. For construction reasons, the rod-shaped element in the given exemplary embodiment can be enclosed by a tube, for example made of aluminium. The compact design facilitates the insertion and positioning in the interior of the optical system and primarily has the effect that if a contaminate, in particular resulting from particles, fluff or fibres, was visualized with the aid of the visualization unit, said contaminate can subsequently be removed directly with the aid of the cleaning unit (305) arranged in direct proximity, without once again displacing the device for cleaning. If the distance between visualization unit (304) and cleaning unit (305) is too large, either the cleaning performance of the cleaning unit (305) is impaired or the cleaning unit (305) has to be displaced once again before cleaning, which entails the risk that the contaminate cannot be removed optimally because it has not been found optimally.

For this purpose, the visualization unit (304), for example a (video)endoscope, a boroscope, a camera, or a detector, is configured to visualize contaminates (320) on the surface (302). The signal can be transmitted towards the outside to an image generator (313), such as a screen, for example. The contaminates on the surface (302) are not illustrated, for the sake of clarity. In this case, the visualization unit (304) serves firstly for finding and for visualizing the contaminates. The contaminates found can then be assessed and, if necessary, be removed from the surface (302) by the cleaning unit (305). Secondly, after the cleaning, the cleaning state can also be verified and documented.

The cleaning unit (305) configured to remove contaminates from the surface (302) can contain for example a suction extractor and/or a means for detaching the contaminates from the surface. In this case, the suction extractor is able to extract the contaminates, particularly if they are particles, fluff or fibres, by suction from the surface. The detaching means can be, for example, a compressed air probe or a CO2 jet unit, which can detach contaminates from the surface with the aid of CO2 pellets or CO2 snow.

Depending on the location or type of the surface (302) in the optical system, it may be sufficient only to detach the contaminate from the surface (302). With the aid of a combination of a suction extractor and a detaching means, however, the contaminates can firstly be detached and then be extracted by suction and thus be completely removed from the optical system (300).

Furthermore, the cleaning unit (305) can also be a surface measuring probe. The latter can firstly detach contaminates with the aid of compressed air and then extract them by suction. The extracted gas is subsequently fed to an analysis unit (314), for example an RGA (Residual Gas Analysis) unit. The exact constitution of the contaminate can thus be examined. The residual gas analysis unit can be a mass spectrometer, for example.

In this case, the distance sensor (306) is integrated into the end of the rod-shaped element (303) such that it can measure the distance between the surface (302) and the end of the rod-shaped element (303). By way of example, the distance sensor is a capacitive or ultrasonic sensor.

This serves for minimising the risk of damage and failure, as well as for effective cleaning of the surfaces. On the one hand, the surface (302) must not be touched, in order to avoid damage to the surface or positional displacements of the elements, specifically of the optical elements. On the other hand, for effective cleaning, the distance between the surface (302) and the end of the rod-shaped element (303) must be less than a maximum distance in order that the cleaning unit (305) functions optimally. Preferably, the cleaning unit (305) must be guided to the surface (302) to be cleaned to a distance of less than 10 mm. Care must be taken here to ensure that the distance sensor (306) functions in all spatial directions, and not just in a direction parallel to the rod-shaped element (303). For this purpose, it is necessary to integrate the distance sensor (306) into the device for cleaning such that shading by the other elements, in particular by the cleaning unit and the visualization unit (304, 305), does not occur.

For cleaning purposes, firstly the connection element (307) is secured at an opening (311 ) of the optical system (300). As already explained above, the openings of the optical system can be an entrance or exit opening for the radiation. Flowever, they can also be openings that arise in the event of maintenance, for example if a submodule is mounted from the optical system. The opening that arises in this case can likewise be used as access for the device for cleaning.

The connection element (307) can furthermore comprise a guide element (308), with the aid of which the rod-shaped element (303) can be guided. Firstly, the rod-shaped element (303) is inserted into the optical system (300) through the opening (311) usually manually, but already being guided by the guide element (308) comprised in the connection element. In this case, by means of the guidance of the rod-shaped element, a controlled movement of the rod-shaped element from the opening of the optical system toward the surface (302) to be cleaned (translation) and also a rotary movement about the pivot of the guide element (rotation) are made possible. Thus the entire surface (302) in the interior can ideally be reached. In the present exemplary embodiment, the guide element can comprise a ball-and-socket joint, which allows a rotary movement about a pivot in addition to translation into the interior of the system.

By this means the rod-shaped element is mounted rotatably about the pivot of the ball- and-socket joint and, given sufficient structural space, can be displaced arbitrarily at both solid angles.

During the process, the distance sensor (306) can output acoustic or optical signals, wherein the signals are such that conclusions about the distance between the surface (302) and the end of the rod-shaped element (303) can be drawn therefrom. This can involve an acoustic signal that varies for example the pitch or the frequency of the signal as the surface (302) is approached more closely, in order to warn the user. It is likewise conceivable for an optical signal to be output instead of or in support of said acoustic signal.

Furthermore, the guide element can comprise a securing unit (309) for securing the rod shaped element, said securing unit not being shown in Fig. 3. Thus, for example at a location of the surface at which a contaminate was visualized by the visualization unit and given a predefined distance, which is measured by the distance sensor, the rod shaped element can be secured and then the cleaning can be carried out without the risk of failure. For this purpose, the rod-shaped element can be clamped with the aid of a screw, for example. The generation of further particles should be avoided or minimized in this case. As an alternative to screwing, clamping by means of an eccentric would also be conceivable. Alternatively the converse principle that the rod shaped element is clamped in the non-actuated state and is made movable by the introduction of force and the associated release of the clamping. The rod-shaped element can also include a kinematic system for angled bending, whereby optical units that are not accessible rectilinearly can be made reachable. Said kinematic system can be simple joints that can be actuated in their degree of freedom.

If the connection element (307) further comprises a displacement unit (310) for fine positioning, the position of the rod-shaped element (303) relative to the surface (302) to be cleaned can then be optimized further by actuation of the displacement unit. It is then possible, for example, after a manual coarse positioning, firstly to fix the rod-shaped element (303) and then, with the aid of the displacement unit (310), to head for the optimum position with regard to the exact location of the contaminate and the optimum distance with respect to the surface (302) with the aid of the visualization unit (304) and the distance sensor (306). In this case, the control can be effected for example with the aid of a (manual) crank or alternatively by way of a controllable actuator. This possibility of fine positioning makes it possible to carry out effective cleaning with a low risk of failure. Diverse actuators that can be used to implement a translational movement are useable as a controllable actuator. For example including actuators that operate according to the piezo-crawler principle or else hydraulically or pneumatically/hydraulically/electrically operated linear drives.

Furthermore, the device for cleaning can comprise an anti-collision protection means (325) which is fitted at the end of the rod-shaped element. Said means can be, in particular, plastic lamellae, PMC tape or Kalrez material. If a surface (302), specifically an optical surface, were indeed touched, it would be better protected by the anti collision protection means (325) and the risk of damage or failure would thus additionally be minimized.

Furthermore, the device for cleaning can comprise a control unit, not shown in Fig. 3. With accurate knowledge of the geometry and location of the surface (302), it is possible to move to the surface (302) in the interior of the optical system (300) in an automated manner with the aid of the control unit and the displacement unit (310), as a result of which automated cleaning of the surface is made possible.

By way of example, it is conceivable for the entire surface (302) to have been recorded beforehand with the aid of a suitable recording device, for example a camera. This may have been effected by means of a single recording or, in the case of larger surfaces, by means of a sequence of recordings that are correspondingly strung together and suitably combined. The surface cartography available as a result can yield the position of the contaminates on the surface given a suitable recording. The data can then be used to move to, and clean, the contaminated locations on the surface in a targeted manner rapidly and effectively with the aid of the control unit.

In this case, the signal of the distance sensor (306) can also be used as an input for the control unit. In this regard, the device for cleaning (305) can also move to the surface (302) in an automated manner with the aid of the displacement unit (310) controlled by the control signal, and efficient and low-risk cleaning can thus be made possible.

Generally, care must be taken to ensure that all materials used in the device for cleaning are permitted to be employed for use in a cleanroom for lithography. This means that the materials used must exhibit little outgassing and few particles and are not permitted to leave any HIO critical materials or any imprints on the surface.

Fig. 4 shows a schematic illustration of a device for cleaning in accordance with a second embodiment of the invention, said device being attached to a lithography system. In this case, for the sake of clarity, the optical system (400) is shown only by a housing (412) having an opening (411) and two optical elements (401, 415) situated in the interior. The surface (402) to be cleaned is the surface of the optical element (401).

In this case, the exemplary embodiment shown in Fig. 4 comprises a rod-shaped element (403) already explained in Fig. 3, which comprises the components of distance sensor (406), visualization unit (404) and cleaning unit (405), these components not being shown in Fig. 4, and a connection element (407), the associated guide element (408). Furthermore, the embodiment can comprise a securing unit (409, not shown) with an optional displacement unit (410) for fine positioning and/or an anti-collision protection means and/or a control unit. These components have been described in detail on the basis of the exemplary embodiment in Fig. 3. Furthermore, the device of the exemplary embodiment shown in Fig. 4 comprises an illumination unit (417) designed in such a way that it illuminates the surface section visualized by the visualization unit (404). This can involve for example a ring electrode or an LED ring, wherein the LED ring is switchable as far as possible sequentially. An improved illumination of the contaminates to be visualized by means of grazing light can thus be achieved. Since the surface (402) to be cleaned is a surface in the interior of the optical system (400), the lighting conditions are not ideal and can be improved by such an illumination unit (417), whereby the cleaning result can be improved.

By way of example, an illumination with different spectra can be effected in this case. In this regard, it is possible to use an illumination with UV light, for example, in which organic contamination can be particularly lit up and identified more easily.

Likewise, an indirect illumination can also lead to a good visualization of the contamination.

In addition, the device for cleaning in Fig. 4 comprises a shield (416), which is fitted to the rod-shaped element (403) in such a way that it can be folded out after insertion into the optical system (400) and is configured such that it blocks extraneous light, in particular back-reflections from other surfaces, such as the surface of the optical element (415), for example, in the folded-out state. Blocking the extraneous light has the effect that only light and thus information passes from the surface section to be visualized into the visualization unit (404) and disturbing superimpositions can be blocked and the visualization and subsequently the cleaning can thus be improved.

The illumination unit is integrated into the shield (416) in the present exemplary embodiment. However, it can also be fitted at the end of the rod-shaped element (403) or directly in the visualization unit (404).

Furthermore, the device for cleaning in the embodiment present in Fig. 4 comprises a means for sampling (418), in particular Kalrez material, a PMC tape or a clean tip, said means being fitted at the end of the rod-shaped element (403). By approaching and touching the surface (402) to be cleaned, the contaminates can be at least partly removed from the optical system and then be viewed and analysed using suitable means, such as a light microscope or a scanning electron microscope (SEM) or other means for sample analysis, for example. Knowledge of the material, under certain circumstances, allows the cause of the contamination to be deduced and then remedied. The embodiment described in Fig. 4 comprises both an illumination unit (417), a shield (416) and a means for sampling (417). Further advantageous embodiments can also comprise only one of the three components mentioned or combinations of in each case two of the components. The embodiments described with reference to Figs 3 and 4 and their modifications can all be used for cleaning a surface (302, 402) in the interior of an optical system (300, 400).

Furthermore, the invention relates to a method for cleaning a surface (302, 402) in the interior of an optical system (300, 400), comprising the steps of securing a connection element (307, 407) at an opening (311, 411) of the optical system, wherein the connection element is adapted to the outer geometry of the optical system and wherein the connection element comprises a guide element (308, 408), inserting a rod-shaped element (303, 403), which comprises a visualization unit (304, 404), a cleaning unit (305, 405) and a distance sensor (306, 406), through the guide element (308, 408) into the interior of the optical system, using the visualization unit (304, 404) for visualizing the contaminate, moving the rod-shaped element (303, 403) to a suitable distance from the surface (302, 402) on the basis of the distance signal of the distance sensor (306, 406), and subsequent cleaning with the aid of the cleaning unit (305, 405).